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Prentice-Hall Chapter 5.1 Dr. Yager

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1 Prentice-Hall Chapter 5.1 Dr. Yager
Models of the Atom Prentice-Hall Chapter 5.1 Dr. Yager

2 Objectives Identify the inadequacies in the Rutherford atomic model.
Identify the Bohr model of the atom and its associated fixed energy levels. Describe the energies and positions of electrons according to the quantum mechanical model. Describe the shapes of atomic orbitals and their relationship to different energy sublevels.

3 The Development of Atomic Models
5.1 The Development of Atomic Models Rutherford’s atomic model could not explain the chemical properties of elements. Rutherford’s atomic model could not explain why objects change color when heated. Rutherford’s model fails to explain why objects change color when heated. As the temperature of this horseshoe is increased, it first appears black, then red, then yellow, and then white. The observed behavior could be explained only if the atoms in the iron gave off light in specific amounts of energy. A better atomic model was needed to explain this observation.

4 The Development of Atomic Models: 1803 -1911
These illustrations show how the atomic model has changed as scientists learned more about the atom’s structure.

5 The Development of Atomic Models: 1913 -1932
These illustrations show how the atomic model has changed as scientists learned more about the atom’s structure.

6 The Bohr Model Niels Bohr ( ) (Rutherford’s student) proposed that an electron is found only in specific circular paths, or orbits, around the nucleus. (think planets around the sun!) Each electron orbit in Bohr’s model has a fixed energy that prevents it from falling into the nucleus. The fixed energies an electron can have are called energy levels. A quantum of energy is the amount of energy required to move an electron from one energy level to another energy level.

7 The Bohr Model Like the rungs of the strange ladder, the energy levels in an atom are not equally spaced. The higher the energy level occupied by an electron, the less energy it takes to move from that energy level to the next higher energy level. The energies of electrons are quantized. These ladder steps are somewhat like energy levels. In an ordinary ladder, the rungs are equally spaced. The energy levels in atoms are unequally spaced, like the rungs in this ladder. The higher energy levels are closer together.

8 5.1 The Bohr model gave results in agreement with experiments for the hydrogen atom, but failed to explain the energies absorbed or emitted by atoms with more than one electron. Need a new theory! The quantum mechanical model determines the allowed energies an electron can have and how likely it is to find the electron in various locations around the nucleus.

9 The Quantum Mechanical Model
5.1 The Quantum Mechanical Model Austrian physicist Erwin Schrödinger (1887–1961) used new theoretical calculations and results to devise and solve a mathematical equation describing the behavior of the electron in a hydrogen atom. The modern description of the electrons in atoms, the quantum mechanical model, comes from the mathematical solutions to the Schrödinger equation.

10 The Quantum Mechanical Model
5.1 The Quantum Mechanical Model The propeller blade of an airplane has the same probability of being anywhere in the blurry region, but you cannot tell its location at any instant. The electron cloud of an atom can be compared to a spinning airplane propeller. The electron cloud of an atom is compared here to photographs of a spinning airplane propeller. a) The airplane propeller is somewhere in the blurry region it produces in this picture, but the picture does not tell you its exact position at any instant. b) Similarly, the electron cloud of an atom represents the locations where an electron is likely to be found.

11 In the quantum mechanical model, the probability of finding an electron within a certain volume of space surrounding the nucleus can be represented as a fuzzy cloud. The cloud is more dense where the probability of finding the electron is high. The electron cloud of an atom is compared here to photographs of a spinning airplane propeller. a) The airplane propeller is somewhere in the blurry region it produces in this picture, but the picture does not tell you its exact position at any instant. b) Similarly, the electron cloud of an atom represents the locations where an electron is likely to be found.

12 5.1 Atomic Orbitals An atomic orbital is often thought of as a region of space in which there is a high probability of finding an electron. Each energy sublevel corresponds to an orbital of a different shape. An atomic orbital represents a mathematical solution to the Schrödinger Equation and is the statistical probability of finding an electron in a defined volume and with a specific energy.

13 5.1 Atomic Orbitals Different atomic orbitals are denoted by letters. The s orbitals are spherical, and p orbitals are dumbbell-shaped. The electron clouds for the s orbital and the p orbitals are shown here.

14 5.1 Atomic Orbitals Four of the five d orbitals have the same shape but different orientations in space. The d orbitals are illustrated here. Four of the five d orbitals have the same shape but different orientations in space. Interpreting Diagrams How are the orientations of the dxy and dx2 – y2 orbitals similar? How are they different?

15 Atomic f Orbitals

16 5.1 Atomic Orbitals The numbers and kinds of atomic orbitals depend on the energy sublevel.

17 5.1 Atomic Orbitals The number of electrons allowed in each of the first four energy levels are shown here.

18 1. Rutherford's planetary model of the atom could not explain
any properties of elements. the chemical properties of elements. the distribution of mass in an atom. the distribution of positive and negative charges in an atom.

19 1. Rutherford's planetary model of the atom could not explain
any properties of elements. the chemical properties of elements. the distribution of mass in an atom. the distribution of positive and negative charges in an atom.

20 2. Bohr's model of the atom proposed that electrons are found
embedded in a sphere of positive charge. in fixed positions surrounding the nucleus. in circular orbits at fixed distances from the nucleus. orbiting the nucleus in a single fixed circular path.

21 2. Bohr's model of the atom proposed that electrons are found
embedded in a sphere of positive charge. in fixed positions surrounding the nucleus. in circular orbits at fixed distances from the nucleus. orbiting the nucleus in a single fixed circular path.

22 3. What is the lowest-numbered principal energy level in which p orbitals are found?
1 2 3 4

23 3. What is the lowest-numbered principal energy level in which p orbitals are found?
1 2 3 4

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