Atomic Models

1. Atomic Models

2. Democritus • 430BC gave the atom it’s name. • Atom: uncuttable • Dark Ages no further work has been recorded • The idea of atoms began to develop again in the 1600’s as people did experiments.

3. John Dalton’s Atomic Theory 1776 • Atoms • Consist of elements that cannot be divided • All atoms of same element are exactly alike and have the same mass. • An atom of one element cannot be changed into an atom of another element. • Compounds are formed when atoms of more than one element are combined.

4. J.J. Thomsen’s model (1897) • Plum pudding or watermelon model • Discovered atoms contain charged particles, positive and negative. • Positive charge must balance negative charge.

5. Ernest Rutherford 1911 • Discovered that atoms are mainly empty space with a positively charged nucleus. • His new model is like a cherry. The dense nucleus surrounded by empty space. • Protons are in the nucleus.

6. Niels Bohr’s Model 1913 • Electrons are found in specific energy levels or orbitals. • Each possible orbit has a fixed energy. Electrons furthest from the nucleus have the highest energy.

7. Modern Model 1932 • Electrons move rapidly within a “cloud” around the nucleus. • Nucleus contains protons and neutrons. • Clouds contain electrons

8. Atomic model videos • History of atom short version • Thomsen’s experiment • History of atom long version • Rutherford’s experiment http://www.youtube.com/watch?v=QbWKF9uDF7w http://www.youtube.com/watch?v=CsjLYLW_3G0 http://www.youtube.com/watch?v=njGz69B_pUg http://www.youtube.com/watch?v=XBqHkraf8iE

9. Periodic Table • Organizes the elements by atomic number, mass and families. • Mendeleev built the periodic table in the 1800’s. http://www.periodictable.com/

10. Counting Particles • Atomic Number Tells you the number of protons and electrons in an element

11. Atomic Mass • Atomic mass tells you the weight of each nucleus. • Nucleus mass = protons + neutrons • Each mass is written in atomic mass units (a.m.u.)

12. How to find # of neutrons • To find # of neutrons, subtract the atomic mass from the atomic # and round. • For example • Oxygen = 15.98 (16) – atomic # (8) = 8 neutrons

13. Models of atoms • Model the atoms nucleus and place electrons in an orbit

14. Neutrons • The bigger the element the more neutrons you will have. • The neutrons hold the nucleus together. • How many neutrons would gold have?

15. Isotopes • Isotopes of an element have same number of protons, different number of neutrons. • That is why atomic mass has decimal parts. The mass is a weighted average like grades.

16. Isotopes • Abundance is how common it is to find in nature. You multiply the weight by the abundance to get the weighted average.

17. Nuclear fusion on sun

18. Patterns of the periodic table • Rows = periods • Each period goes from metals to metalloids to nonmetals.

19. Real periodic table

20. Cylinder periodic table

21. Groups of the periodic table • Groups are known as families • Elements in each family have similar chemical properties. • The elements in a family all have the same valence (outermost) # of electrons.

22. Alkali metals • Most reactive metals in the periodic table. • Never found uncombined in nature • Have 1 valence electron • Sodium (salt) reactivity of alkali metals

23. Alkaline Earth • Group 2 elements • Less reactive than alkali metals, but still reactive. • Calcium – found in bones, teeth • Have 2 valence electrons alkaline earth metals

24. Transition Metals • Groups 3-12 • Iron, copper, gold, nickel, silver • Hard and shiny solids, except mercury at room temperature. • Good conductors of heat and electricity. • Less reactive than Group 1 or 2

25. Properties of metals • All metals transfer electrons to become stable when they are reacted with a nonmetal.

26. Metalloids • Some properties of metals and some of nonmetals. • Solids at room temperature • Conductivity most important property. • Silicon and germanium are used to make chips for computers/cellphones etc.

27. Nonmetals • Groups 13-18 • Lacks most of the properties of metals. • Poor conductors of heat and electricity • Brittle as solids • Many are gases at room temperature • Carbon, Sulfur, and iodine are solids at room temperature

28. Properties • Gain or share(covalently) electrons to become stable. • When metals bond with nonmetals the metal transfers it’s electrons to the nonmetal. i.e. salt • When nonmetals bond with nonmetals the elements share electrons. i.e. water

29. Jigsaw Element Project • You are to choose one of the elements in your family. • You will need to make a visual aid (2D or 3D) of your element and use to present to the class. • All information required must be included in your poster/ and or presentation. • You will present as a group, each person must have a part.

30. Requirements • Atomic Symbol (atomic number, atomic mass) • # of protons, electrons, and neutrons • Correct model of atom • Physical properties of the element • # of valent electrons in family • Common uses of the element and/or compounds made from the element. • Similarities and differences to other elements in the family.

31. Rubric Visual aid • Contains required information 20 pts. • Follows ABCD 10 pts. (accurate, big, colorful, detailed) Group work 10 pts. • All group members were on task and used class time wisely. • Group met the timeline 10 pts.

32. Rubric Continued Presentation • All group members presented 10 pts. • Voices/Eye Contact (average) 10 pts. • Attentive to other presentations 10 pts.

33. Timeline • You will have two days and the weekend to get your project done and presented.

34. Carbon Family

35. Nitrogen family

36. Oxygen Family

37. Halogen family

38. Noble Gases

39. Metalloids