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Quantum Mechanical Model of the Atom

Quantum Mechanical Model of the Atom. Problem with Bohr’s Model. Bohr’s model of the atom could not explain why the spectra of other elements had too many lines. What appeared to be a single line in a spectrum was actually several lines closely grouped together. Modified Bohr Model.

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Quantum Mechanical Model of the Atom

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  1. Quantum Mechanical Model of the Atom

  2. Problem with Bohr’s Model • Bohr’s model of the atom could not explain why the spectra of other elements had too many lines. What appeared to be a single line in a spectrum was actually several lines closely grouped together.

  3. Modified Bohr Model • By breaking Bohr’s energy levels into sublevels, it was possible to explain these spectra. Therefore, an energy level is actually made up of many energy states that are closely grouped together. • Bohr’s levels were broken into the following sublevels: Sharp Principle Diffuse Fundamental

  4. Each sublevel holds a different number of electrons

  5. Orbitals • The space occupied by a pair of electrons is called an orbital. Each orbital can hold one pair of electrons. Orbital describe regions in space where is electron is more likely to be found.

  6. Sublevels

  7. Energy levels and multi-electron atoms • To construct a model of an atom, follow these two rules: (1) Aufbau Principle – Electrons always enter orbitals of the lowest energy first. (2) There is a maximum number of electrons for each energy level. The number is given by 2n2 where n is the principle quantum number.

  8. Pauli Exclusion Principle • An atomic orbital may describe at most two electrons. To occupy the same orbitals, two electrons must have opposite spins. Spin is a quantum property of electrons and may be clockwise (represented by an upward pointing arrow ↑) or counterclockwise (represented by a downward pointing arrow ↓).

  9. Hund’s Rule • When electrons occupy orbitals of equal energy, one electron enters each orbital until all the orbitals contain one electron with spins parallel (either all the spins are clockwise or all the spins are counterclockwise). Second electrons then add to each orbital so that their spins are paired with the first electrons in the orbital.

  10. Steps to Writing the Electron Configuration of an Atom • Step 1 • Get a Periodic Table of Elements • Find out how many electrons the atom has. On the periodic table, the atomic number is the number of protons of the atom, and thus equals the number of electrons in an atom with zero charge.

  11. Step 2: Mnemonic for Filling Orbitals

  12. Step 3 • Put one electron into the highest energy orbital available, starting with 1s (holds a maximum of two electrons). Fill the orbitals in this order (the number in superscript following the sublevel is the maximum number of electrons it can hold): • 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 6s2 4f14 5d10 6p6 7s2 5f14 6d10 • Note: Energy level changes as you go up. For example, when you are about to go up to the 4th energy level, it becomes 4s first, then 3d. After the fourth energy level, you'll move onto the 5th where it follows the order once again. This only happens after the 3rd energy level!

  13. Step 4 • Once you've put every electron into an orbital (according to the order), write the configuration as shown at the end of step 3. Only write the orbitals that contain electrons. • So, an uncharged antimony atom's electron configuration would be 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p3. Notice that the superscript number following 5p is 3. That's because only three electrons are in the 5p sublevel, so the sublevel is not completely occupied (it lacks three more electrons).

  14. Practice • Write the electron configuration for the first 20 elements. • Write the electron configuration of Br, Ag, Ba, Au, and U.

  15. Energy Level Diagrams • The electron configuration of atoms can also be shown in energy level diagrams. In such diagrams, individual orbital are represented by spheres, boxes, or lines. Each orbital can hold a maximum of 2 electrons containing opposite spins. The height of each orbital is representative of its energy. The higher the orbital is in the diagrams, the higher is its energy.

  16. Example using spheres for orbitals

  17. Examples • I will use boxes to represent individual orbitals. Examples • Hydrogen Oxygen Potassium

  18. Practice • Draw the energy level diagram for the following: Lithium Fluorine Silver

  19. Electron Orbital Shapes

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