1. CHEMISTRY Matter and Change
Chapter 6: The Periodic Table and Periodic Law

2. Table Of Contents Section 6.1 Development of the Modern Periodic Table
CHAPTER6
Table Of Contents
Section 6.1 Development of the Modern Periodic Table
Section 6.2 Classification of the Elements
Section 6.3 Periodic Trends
Click a hyperlink to view the corresponding slides.
Exit

3. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Trace the development of the periodic table.
Identify key features of the periodic table.
atomic number: the number of protons in an atom
The periodic table evolved over time as scientists discovered more useful ways to compare and organize the elements.

4. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
periodic law
group
period
representative elements
transition elements
metal
alkali metals
alkaline earth metals
transition metal
inner transition metal
lanthanide series
actinide series
nonmetals
halogen
noble gas
metalloid

5. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Development of the Periodic Table
In the 1700s, Lavoisier compiled a list of all the known elements of the time.

6. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Development of the Periodic Table (cont.)
The 1800s brought large amounts of information and scientists needed a way to organize knowledge about elements.
John Newlands proposed an arrangement where elements were ordered by increasing atomic mass.

7. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Development of the Periodic Table (cont.)
Newlands noticed when the elements were arranged by increasing atomic mass, their properties repeated every eighth element.

8. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Development of the Periodic Table (cont.)
Meyer and Mendeleev both demonstrated a connection between atomic mass and elemental properties.
Moseley rearranged the table by increasing atomic number, and resulted in a clear periodic pattern.
* is called periodic law.

9. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Development of the Periodic Table (cont.)

10. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table
The modern periodic table contains boxes which contain the element's name, symbol, atomic number, and atomic mass.

11. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)
* are called groups.
* are called periods.
Elements in groups 1,2, and possess a wide variety of chemical and physical properties and are called the representative elements.
* are known as the transition metals.

12. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)
Elements are classified as metals, non-metals, and metalloids.
Metals are elements that are generally shiny when smooth and clean, solid at room temperature, and good conductors of heat and electricity.
Alkali metals are all the elements in *
Alkaline earth metals are in *

13. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)
The transition elements are divided into transition metals and inner transition metals.
The two sets of inner transition metals are called the lanthanide series and actinide series and are located at the bottom of the periodic table.

14. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)
Non-metals are elements that are generally *
Group 17 is composed of highly reactive elements called halogens.
Group 18 gases are extremely unreactive and commonly called noble gases.

15. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)
Metalloids have physical and chemical properties of both metals and non-metals, such as silicon and germanium.

16. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
The Modern Periodic Table (cont.)

17. Classification of the Elements
SECTION6.2
Classification of the Elements
Explain why elements in the same group have similar properties.
valence electron: electron in an atom's outermost orbitals; determines the chemical properties of an atom
Identify the four blocks of the periodic table based on their electron configuration.
Elements are organized into different blocks in the periodic table according to their electron configurations.

18. Classification of the Elements
SECTION6.2
Classification of the Elements
Organizing the Elements by Electron Configuration
Recall electrons in the highest principal energy level are called valence electrons.
All group 1 elements have one valence electron.

19. Classification of the Elements
SECTION6.2
Classification of the Elements
Organizing the Elements by Electron Configuration (cont.)
The energy level of an element’s valence electrons indicates the period on the periodic table in which it is found.
The number of valence electrons for elements in groups is ten less than their group number.

20. Classification of the Elements
SECTION6.2
Classification of the Elements
Organizing the Elements by Electron Configuration (cont.)

21. Classification of the Elements
SECTION6.2
Classification of the Elements
The s-, p-, d-, and f-Block Elements
The shape of the periodic table becomes clear if it is divided into blocks representing the atom’s energy sublevel being filled with valence electrons.

22. Classification of the Elements
SECTION6.2
Classification of the Elements
The s-, p-, d-, and f-Block Elements (cont.)
s-block elements consist of group 1 and 2, and the element helium.
Group 1 elements have a partially filled s orbital with one electron.
Group 2 elements have a completely filled s orbital with two electrons.

23. Classification of the Elements
SECTION6.2
Classification of the Elements
The s-, p-, d-, and f-Block Elements (cont.)
After the s-orbital is filled, valence electrons occupy the p-orbital.
Groups contain elements with completely or partially filled p orbitals.

24. Classification of the Elements
SECTION6.2
Classification of the Elements
The s-, p-, d-, and f-Block Elements (cont.)
The d-block contains the transition metals and is the largest block.
There are exceptions, but d-block elements usually have filled outermost s orbital, and filled or partially filled d orbital.
The five d orbitals can hold 10 electrons, so the d-block spans ten groups on the periodic table.

25. Classification of the Elements
SECTION6.2
Classification of the Elements
The s-, p-, d-, and f-Block Elements (cont.)
The f-block contains the inner transition metals.
f-block elements have filled or partially filled outermost s orbitals and filled or partially filled 4f and 5f orbitals.
The 7 f orbitals hold 14 electrons, and the inner transition metals span 14 groups.

26. Periodic Trends Compare period and group trends of several properties.
SECTION6.3
Periodic Trends
Compare period and group trends of several properties.
principal energy level: the major energy level of an atom
Relate period and group trends in atomic radii to electron configuration.
ion
ionization energy
octet rule
electronegativity
Trends among elements in the periodic table include their size and their ability to lose or attract electrons

27. Periodic Trends Atomic Radius
SECTION6.3
Periodic Trends
Atomic Radius
Atomic size is a periodic trend influenced by electron configuration.
For metals, atomic radius is half the distance between adjacent nuclei in a crystal of the element.

28. Periodic Trends Atomic Radius (cont.)
SECTION6.3
Periodic Trends
Atomic Radius (cont.)
For elements that occur as molecules, the atomic radius is half the distance between nuclei of identical atoms.

29. Periodic Trends Atomic Radius (cont.)
SECTION6.3
Periodic Trends
Atomic Radius (cont.)
There is a general decrease in atomic radius from left to right, caused by increasing positive charge in the nucleus.
Valence electrons are not shielded from the increasing nuclear charge because no additional electrons come between the nucleus and the valence electrons.

30. SECTION6.3
Periodic Trends
Atomic Radius (cont.)

31. Periodic Trends Atomic Radius (cont.) Atomic radius generally *.
SECTION6.3
Periodic Trends
Atomic Radius (cont.)
Atomic radius generally *.
The outermost orbital size *.

32. Periodic Trends Ionic Radius An ion is *
SECTION6.3
Periodic Trends
Ionic Radius
An ion is *
When atoms lose electrons and form positively charged ions, they always become smaller for two reasons:
The loss of a valence electron can leave an empty outer orbital resulting in a small radius.
Electrostatic repulsion decreases allowing the electrons to be pulled closer to the radius.

33. Periodic Trends Ionic Radius (cont.)
SECTION6.3
Periodic Trends
Ionic Radius (cont.)
When atoms gain electrons, they can become larger, because the addition of an electron increases electrostatic repulsion.

34. Periodic Trends Ionic Radius (cont.)
SECTION6.3
Periodic Trends
Ionic Radius (cont.)
The ionic radii of positive ions generally decrease from left to right.
The ionic radii of negative ions generally decrease from left to right, beginning with group 15 or 16.

35. Periodic Trends Ionic Radius (cont.)
SECTION6.3
Periodic Trends
Ionic Radius (cont.)
Both positive and negative ions increase in size moving down a group.

36. Periodic Trends Ionization Energy Ionization energy is defined as *
SECTION6.3
Periodic Trends
Ionization Energy
Ionization energy is defined as *
The energy required to remove the first electron is called the first ionization energy.

37. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)

38. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)
Removing the second electron requires more energy, and is called the second ionization energy.
Each successive ionization requires more energy, but it is not a steady increase.

39. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)

40. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)
The ionization at which the large increase in energy occurs is related to the number of valence electrons.
First ionization energy increases from left to right across a period.
First ionization energy decreases down a group because atomic size increases and less energy is required to remove an electron farther from the nucleus.

41. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)

42. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)
The octet rule states that *.
The octet rule is useful for predicting what types of ions an element is likely to form.

43. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)
The electronegativity of an element indicates its relative ability to *
Electronegativity decreases down a group and increases left to right across a period.

44. Ionization Energy (cont.)
SECTION6.3
Periodic Trends
Ionization Energy (cont.)

45. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Study Guide
Key Concepts
The elements were first organized by increasing atomic mass, which led to inconsistencies. Later, they were organized by increasing atomic number.
The periodic law states that when the elements are arranged by increasing atomic number, there is a periodic repetition of their chemical and physical properties.
The periodic table organizes the elements into periods (rows) and groups (columns); elements with similar properties are in the same group.

46. Development of the Modern Periodic Table
SECTION6.1
Development of the Modern Periodic Table
Study Guide
Key Concepts
Elements are classified as either metals, nonmetals, or metalloids.

47. Classification of the Elements
SECTION6.2
Classification of the Elements
Study Guide
Key Concepts
The periodic table has four blocks (s, p, d, f).
Elements within a group have similar chemical properties.
The group number for elements in groups 1 and 2 equals the element’s number of valence electrons.
The energy level of an atom’s valence electrons equals its period number.

48. Periodic Trends Key Concepts
SECTION6.3
Periodic Trends
Study Guide
Key Concepts
Atomic and ionic radii decrease from left to right across a period, and increase as you move down a group.
Ionization energies generally increase from left to right across a period, and decrease as you move down a group.
The octet rule states that atoms gain, lose, or share electrons to acquire a full set of eight valence electrons.
Electronegativity generally increases from left to right across a period, and decreases as you move down a group.