1. Chapter 5
Electrons in Atoms

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

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

4. Dalton model of Atom Atom tiny, indestructible particles
No internal structure

5. Thomson model Plum-pudding Sphere with +ve charge throughout
e- embedded in a sphere of +ve electrical charge

6. Rutherford Model Atom has a small, dense, +vely charged nucleus
e- move around the nucleus

7. Electrons in Motion Bohr proposed that e- must have enough energy
to keep them in constant motion around the
nucleus.
e- have k.e. that enables them to overcome the attraction of the +ve nucleus.

8. Electrons in Motion
This energy keeps the e- moving around the nucleus. B
Bohr’s: planetary model. A C

9. Bohr model
e- moves in a circular orbit at fixed distances from nucleus

10. Bohr Model Each possible e- orbit in Bohr’s model has a fixed energy.
Energy levels:
The fixed energies an e- can have.
A quantum of energy
is the amt of energy required to move 1 e- from 1 EL to a higher EL.

11. QW
Under what condition will an e- jump from a lower EL to a higher EL?

12. Evidence for Energy Levels (1)
ground state excited state
Higher EL
Lower EL

13. e- Arrangement in Atoms
If this rock were to tumble over, it would end up at a lower height. It would have less energy than before, but its position would be more stable.
Energy and stability play an important role in determining how e- are configured in an atom.

14. Evidence for Energy Levels (2)
Bohr:
e- can have only certain amts of energy (k.e.)
move around the nucleus
only at distances that correspond to those amts of energy.
Energy levels
regions of space in which e- can move about the nucleus of an atom.

15. e- Cloud Model
EL are not neat, planetlike orbits around the nucleus of an atom.
Instead, …‘3-d’ regions of space around the nucleus in which e- are most likely to be found.

16. e- Cloud Model
e- themselves take up little space but travel rapidly thru the space (3-d) surrounding the nucleus.
These ‘3-d’ regions where e- travel may be depicted as clouds around the nucleus.
e- cloud
the space around the nucleus of an atom where the e- are found.

17. Quantum Mechanical Model
The propeller blade has the same probability of being anywhere in the blurry region, but you cannot tell its location at any instant. (cannot see the blades when spinning
The e- 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 e- cloud of an atom represents the locations where an e- is likely to be found.

18. Quantum Mechanical Model
The modern description of the e- in atoms, the quantum mechanical model

19. e- Cloud Model Probable locations of e- in an atom
Denser region → higher probability of finding an e-
denser region is closer to nucleus

20. Quantum Mechanical Model
The probability of finding an e- within a certain volume (3-d) of space surrounding the nucleus can be represented as a fuzzy cloud.
The cloud is denser where the probability of finding the e- is higher.
The e- 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 e- cloud of an atom represents the locations where an e- is likely to be found.

21. Orbitals
The e- Cloud Model is based on the probability of finding an e- in a certain region of space at any given instant.
e- are distributed into sublevels and orbitals in the way that creates the most stable arrangement----lowest energy.

22. e- Cloud Model

23. Electrons in Energy Level (3)
Valence e-
the e- in the outermost (highest) EL.
determine chem properties of the elements.
elements in the same gp have similar chem properties

24. # of Valence e- Use the PT as a tool to predict the # of valence e-
Group #
Group 1 2 13 16 17 18 1A 2A 3A 6A 7A 8A
Rule
Same as group #
Gp # – 10
# valence e- 3 6 7 8

25. e- in Energy Level (4)
An O atom has 8 e-. 2 of these fill the 1st EL, and the remaining 6 are in the 2nd EL.

26. Lewis Dot Diagrams (1)
Because valence e- are so important to the behavior of an atom, it is useful to represent them with symbols.

27. Lewis Dot Diagrams (2)
A Lewis dot diagram illustrates valence e- as dots around the chem symbol.

28. Lewis Dot Diagrams (3) Each dot represents 1 valence e-.
The element’s symbol represents the core of the atom—the nucleus plus all the inner e-.

29. Quantum Mechanical Model
The quantum mechanical model determines the allowed energies an e- can have and how likely it is to find the e- in various locations around the nucleus.

30. Atomic Orbitals
An atomic orbital is often thought of as a region of space in which there is a high probability of finding an e-.
Each energy sublevel corresponds to an orbital of a different shape, which describes where the e- is likely to be found.

31. CST Problem 1
When a metal is heated in a flame, the flame has distinctive color. This information was eventually extended to the study of stars because
A the color spectra of stars indicate which elements are present
B a red shift in star color indicates stars are moving away.
C star color indicates absolute distance.
D it allows the observer to determine the size of stars.

32. CST Example 2
Which statement best describe the density of an atom’s nucleus?
A the nucleus occupies most of the atom’s volume but contains little of its mass.
B the nucleus occupies very little of the atom’s volume and contains little of its mass.
C the nucleus occupies most of the atom’s volume and contains most of its mass.
D The nucleus occupies very little of the atom’s volume but contains most of its mass.

33. The End