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In 1700, only 13 elements had been discovered. As chemists began using the scientific method to search for elements, the rate of discovery increased.

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Presentation on theme: "In 1700, only 13 elements had been discovered. As chemists began using the scientific method to search for elements, the rate of discovery increased."— Presentation transcript:

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2 In 1700, only 13 elements had been discovered. As chemists began using the scientific method to search for elements, the rate of discovery increased. How would chemists known when they found them all? They needed a logical way to organize the elements. Chemists used the properties of elements to sort them into groups

3 J.W. Dobereiner (1780-1849) published a classification system in which elements were grouped in triads. triad: a set of three elements with similar properties. all the known elements couldn’t fit in triads

4 Dmitri Mendeleev (1869) arranged elements in a periodic table in order of increasing atomic mass. Left spaces for he predicted that elements would be discovered to fill in those spaces Predicted their properties based on their location in the table Had problems organizing by atomic mass

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6 Other Scientist Lothar Meyer – later in 1869, published a nearly identical table as Mendeleev H.G.J. Moseley (1913) – determined the atomic number for each known element Modern periodic table is organized by atomic number

7 Periodic Law When elements are arranged in order of increasing atomic number, there is a periodic repetition of their physical and chemical properties

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9 Modern Periodic Table 1. What are groups? Vertical columns 2. What is another name for a group? families 3. What are the periods? Horizontal rows 4. What group is oxygen in? 16 5. What period contains potassium? 4

10 PT There are three main categories in which the elements are divided: metals, nonmetals, and metalloids. The metals are to the left (6) of the jagged line. The nonmetals are to the right (7) of the jagged line. The metalloids are along (8) the jagged line.

11 9. What category do most of the elements fall into? metals 10. What are some characteristics of metals? Shiny, good conductors of heat and electricity, most are solid at room temperature, malleable, and ductile 11. What are some characteristics of nonmetals? Not shinny, poor conductors of heat and electricity, most are gases at room temperature, not malleable, not ductile

12 Metalloids 12. Metalloids have characteristics of both metals and nonmetals. There are only eight metalloids. Which elements are metalloids? Boron, Silicon, Germanium, Arsenic, Antimony, Tellurium, Polnium, Astatine

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14 Family Names 13. Which group is called the alkali metals? 1 14. Which group is called the alkaline earth metals? 2 15. Which groups are called the transition metals? 3-12 16. Where are the inner transition metals found? At the bottom of the table 17. Which group is called the halogens? 17 18. Which group is called the noble gases? 18

15 Block Names 19. Where’s the s-block? 1-2 20. Where’s the p-block? 13-18 21. Where’s the d-block? 3-12 22. Where’ s the f-block? At the bottom

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17 Notes on Valence Electrons The chemical properties of elements are determined by the number of their valence electrons. 23. What are valence electrons? Electrons in the highest principle energy level, the outermost e-

18 Valence Electrons To find the number of valence electrons, find the highest quantum number in the electron configuration. Add up the electrons that have that quantum number. 24. How many valence electrons does sulfur have? 6 (#16) 25. How many valence electrons does cesium have? 1 (#55) 26. How many valence electrons does francium have? 1 (#87)

19 Valence Electrons 27. Write out the shortcut electron configuration for H, Li, Na, and K and determine the number of valence electrons. H: 1s 1  1 ve - Na: [Ne]3s 1  1 ve - Li: [He]2s 1  1 ve - K: [Ar]4s 1  1 ve -

20 VE- Continued 28. All four of those elements are in what group? 1 29. What do all four have in common? All have one valence electron 30. This is not a coincidence. All elements in the same group have the same number of valence electrons. Therefore, what else do they have in common? Same chemical property

21 VE - from Periodic Table 31. How many valence electrons do elements in group 2 have? 2 32. How many valence electrons do elements in group 13 have? 3 33. How many valence electrons do elements in group 14 have? 4 34. How many valence electrons do elements in group 15 have? 5 35. How many valence electrons do elements in group 16 have? 6 36. How many valence electrons do elements in group 17 have? 7 37. How many valence electrons do elements in group 18 have? 8

22 D-Block 38. All elements in the d-bock have the same number of valence electrons. How many? 2

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24 Atomic Radius 1. How is atomic radius defined? Half the distance between the nuclei of the two atoms of the same element when the atoms are joined 2. What is the atomic radius trend within a period? Explain this trend. Increases to the left L  R: With increased number of protons, there is a stronger pull of the outer shell to the nucleus 3. What is the atomic radius trend within a group? Explain this trend. Increases to the bottom Top  Bottom: As you add energy levels you increase the shielding effect from protons, inward pull 4. Which has the largest atomic radius: C, F, Be, or Li? Li > Be> C > F

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26 Ionic Radius 5. What is an ion? Atom with a + or – charge, due to the loss or gain of electrons, respectively 6. When atoms lose electrons, they become positive and smaller. Why? Greater nuclear pull 7. When atoms gain electrons, they become negative and larger. Why? Greater electron repulsion

27 Ionic Radius 8. What is the ionic radius trend within a period? Increases left for cations and anions 9. What is the ionization radius trend within a group? Increases as you go down

28 Ionization Energy 10. What is ionization energy? Energy required to remove an e- from an atom 11. Write the chemical equation which demonstrates what is going on when a positive ion is formed? Li  Li + + e-

29 Ionization Energy 12. A high ionization energy indicates that the atom has a strong hold over its electrons. 13. A low ionization energy indicates that the atom has a weak hold over its electrons. 14. Once you remove one electron, is it harder or easier to remove another one? Why? Harder; protons have a stronger pull on fewer electrons.

30 Ionization Energy 15. For each element there is a huge jump in the ionization energy required at some point in taking away electrons. How does this relate to valence electrons? Once valence electrons are gone, almost impossible to take another because that is when it is most stable 16. What is the ionization energy trend within a period? Explain. Increase to the right; nuclear charge increases to the right and shielding effect remain constant 17. What is the ionization energy trend within a group? Explain. Increase going up; as size increases, nuclear charge has a smaller effect on valence electrons, therefore less energy to remove

31 Electronegativity 18. What is electronegativity? The ability of an atom of an element to attract electrons when the atom is in a compound 19. Why do noble gases not have electronegativity values? Don’t form many compounds 20. What is the electronegativity trend within a period? Increases toward the right 21. What is the electronegativity trend within a group? Increases toward the top F has the greatest electronegativity

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