1. Organization of the Periodic Table

2. Periods –
horizontal rows on the PT
Increase by atomic number
Group/Family –
vertical column on the PT
contain elements with similar properties

3. Alkali Metals – 1st Column on Left Side (Group 1)
Start with Lithium (Li)
Highly reactive metals (especially with water/water vapor)
Never found uncombined in nature
Form 1:1 ratio chloride compounds (metal:Cl)
Form 2:1 ratio oxide compounds (metal:O)

4. Alkaline Earth Metals 2nd column on Left (Group 2) Reactive metals
Form 1:2 ratio chloride compounds (metal:Cl)
Form 1:1 ratio oxide compounds (metal:O)

5. Noble Gases Far right column on the PT
Very unreactive (Chemically inert) elements
All gases
Xenon (Xe) and Krypton (Kr) can form some compounds

6. Halogens Column next to noble gases Highly reactive nonmetals
Form binary compounds with Hydrogen (H)
Binary compounds – made of 2 elements

7. So…
By knowing the major properties of a certain chemical family, you can predict some properties of any element in that family!!!

8. Predicting properties
Periodic properties – properties that vary among elements according to trends that repeat as atomic number increases
Because of these trends, some element properties can be estimated by averaging info from other atoms in the same family.
Ex: Mendeleev predicted Ge based on the known properties of other elements in the family.
Mendeleev believed this he left blanks in his table and used this method to predict other elements

9. Example:
Given that the density of silicon (Si) is 2.3 g/cm3 and the density of tin (Sn) is 7.3 g/cm3, estimate the density of germanium (Ge).
These three elements are in the same group in the periodic table. Germanium is below silicon and above tin. The predicted density of germanium can be estimated by averaging the densities of silicon and tin, arriving at a calculated value of 4.8 g/cm3.
When germanium was discovered in 1886, its density was found to be 5.3 g/cm3, which is within ~10% of the earlier estimated density.

10. What else can be predicted?
Formulas for chemical compounds can also be predicted from relationships in the periodic table. For example, carbon and oxygen form carbon dioxide (CO2). 
What formula would be predicted for a compound of carbon and sulfur? 
The periodic table indicates that sulfur (S) and oxygen (O) are in the same family. Knowing that carbon and oxygen form CO2, a logical—and quite correct—prediction would be CS2 (carbon disulfide). 

11. Now it’s your turn.
The element krypton (Kr) was not known in Mendeleev’s time. Given that the boiling point of argon (Ar) is −186 °C and of xenon (Xe) is −107 °C, estimate the boiling point of krypton.
Estimate the melting point of rubidium (Rb). The melting points of potassium(K) and cesium (Cs) are 337 K and 302 K, respectively.
Do you expect the melting point of sodium (Na) to be higher or lower than that of rubidium (Rb)? Explain. On what evidence did you base your answer?

12. C and F Al and S K and CI Ca and Br Sr and O
Mendeleev knew that silicon tetrachloride (SiCl4) existed.  Predict the formula for the compound formed by germanium and chlorine.
Here are formulas for several known compounds: Nal, MgCl2, CaO, Al2O3, and CCl4. Using that information, predict the formula for a compound formed from:
C and F
Al and S
K and CI
Ca and Br
Sr and O

13. Elemental nickel is white to light gray in color, highly ductile, lustrous, and resistant to tarnish. Which other element would you expect to share these properties: Pt, Cu, Rb, or Kr? Explain your choice.
Manganese, which has melting point 1519 K and is one of the metals used in the Presidential dollar coin, was the only known element in its family for 150 years. When rhenium, which has melting point 3459 K, was discovered in 1925, what could chemists predict about the melting point of element 43?