1. Periodic Table And the Periodic Law

2. Dmitri Mendeleev Russian chemist Created a table by arranging elements according to atomic masses Noticed that chemical properties of the elements followed a repeating pattern

3. Periodic Law –Henry Moseley who worked with Ernest Rutherford was the scientist who improved on Mendeleev’s periodic table by ordering the elements by the number of protons – the atomic number. The physical and chemical properties of the elements are periodic functions of their atomic numbers.

4. Mendeleev left spaces in his periodic table and predicted the existence of 3 elements and their 1.Atomic numbers 2.Colors 3.Properties 4.Radioactivity

5. Arrangement of the table The periodic table is an arrangement of the elements in order of their atomic numbers so that elements with similar properties fall in the same column or group.

6. Groups of the Periodic Table 1 st column (gold) alkali metals 2 nd column (purple) alkaline earth metals 3 rd -12 th Transition Metals 17 th column – halogens 18 th – Noble Gases

7. Electron Configuration and the Periodic Table The periodic table can be divided into blocks which indicate which orbitals are filling.

8. s Block – Groups 1and 2 All are chemically reactive metals Metals in group 1 (alkali metals) are more reactive than metals in group 2 (alkaline earth metals) Neither are found in nature as elements since they react readily with water and nonmetals.

9. Which is more reactive, magnesium or sodium? 1.Magnesium (Mg) 2.Sodium (Na)

10. Name the element [Ar] 4s 2 1.Sodium 2.Potassium 3.Calcium 4.Strontium

11. Alkali Metals Video

12. Hydrogen and Helium Hydrogen is not an alkali metal. Hydrogen is a unique element. Helium is placed with the noble gases Helium has a full outer shell of electrons. Helium is a colorless gas, not a reactive metal.

13. d Block – Groups 3-12 Some of these elements don’t follow the diagonal rule exactly in electron distribution Metals with typical metallic properties. –Good conductors of electricity –High luster Called the transition elements. Less reactive than s block metals

14. Name the element [Ar]4s 2 3d 5 1.Bromine 2.Iron 3.Magnesium 4.Manganese

15. p block – groups 13 – 18 except helium p block and s block together are called the main group elements Properties of this group vary –On the right side – nonmetals –On the left – metals –In between – metalloids (boron, silicon, germanium, arsenic, antimony, tellurium)

16. Metals, Nonmetals, Metalloids Metal- element that is shiny and malleable, and conducts heat and electricity Nonmetal – Conducts heat and electricity poorly and is brittle Metalloid – Element that has the properties of both metals and nonmetals, sometimes called a semiconductor

17. An element which is shiny and brittle is likely a 1.Metal 2.Nonmetal 3.Metalloid 4.s-block element

18. p-block Group 17 – Halogens (fluorine, chlorine, bromine, iodine, astatine) –Most reactive nonmetals Group 18 – Noble Gases (helium, neon, argon, krypton, xenon, radon) –Nonreactive and stable

19. f-block: Lanthanides and Actinides Lanthanides are shiny metals, with reactivity similar to the alkaline earth metals Actinides are all radioactive, many are man-made

20. Name the group 1.Alkali metals 2.Alkaline earth metals 3.Halogens 4.Noble Gases

21. Name the group 1.Alkali metals 2.Alkaline earth metals 3.Halogens 4.Noble gases

22. Name the section of the table 1.S block 2.P block 3.D block 4.F block

23. What types of elements make up the p block? 1.Metals 2.Nonmetals 3.Metalloids 4.All of the above

24. Periodic Trends The arrangement of the periodic table shows directional trends for various properties of the atoms of each element.

25. Nuclear Charge and Atomic Radius Atoms decrease in size from left to right on the periodic table because of the increase in nuclear charge.

26. IN A ROW IN THE PERIODIC TABLE, AS THE ATOMIC NUMBER INCREASES, THE ATOMIC RADIUS 1.Decreases 2.Remains constant 3.Increases 4.Becomes immeasurable

27. Within a group of elements,as the atomic number increases, the atomic radius 1.Increases 2.Remains constant 3.Decreases 4.Varies unpredictably

28. Ionization Energy The energy required to remove an electron from a neutral atom of an element. –A large ionization energy shows that the electrons of an atom are bound more tightly to the nucleus and it is more difficult to remove the electron.

29. Which group of elements has the highest ionization energies? 1.Alkali metals 2.Halogens 3.Noble gases 4.Alkaline earth metals

30. The energy required to remove an electron from an atom is called the 1.Electron affinity 2.Electron energy 3.Electronegativity 4.Ionization energy

31. Ionization Energy (IE) Trends IE generally increases across each period. –As the nuclear charge increases, the electrons are held more tightly IE decreases down a group –As the electrons reside farther from the nucleus, they can be removed more easily.

32. Valence Electrons The electrons available to be lost, gained, or shared in the formation of chemical compounds are referred to as the valence electrons. Valence electrons are those filling s and p orbitals.

33. Valence electrons are those s and p electrons 1.Closest to the nucleus 2.In the lowest energy level 3.In the highest energy level 4.Combined with protons

34. The number of valence electrons in Group 17 elements is 1.7 2.8 3.17 4.Equal to the period number

35. The electrons available to be lost, gained or shared when atoms form compounds are called 1.Ions 2.Valence electrons 3.d electrons 4.Electron clouds

36. Electronegativity A measure of the ability of an atom in a chemical compound to attract electrons from another atom in the compound. Fluorine is assigned a value of 4 and all other elements have values relative to it.

37. The element that has the greatest electronegativity is 1.Oxygen 2.Sodium 3.Chlorine 4.Fluorine

38. Higher Electronegativity Smaller atoms have higher electronegativity. Higher coulombic attraction extends to electrons of other atoms that are involved in a covalent bond.

39. Noble Gases There is no value for electronegativity of noble gases, since they are not generally involved in bonding.