1. Subatomic Particles

2. Electron -ve charged particle Outside of nucleus Thomson’s discovery Mass = 9.11 x 10 -28 g Charge = -1.76 x 10 8 C (coulombs)

3. Proton +ve charged particle Inside nucleus Rutherford’s discovery Mass = 1.67 x 10 -24 g (1836x heavier than electron) Charge = +1.76 x 10 8 C (opposite electron)

4. Neutron No charge Inside nucleus Chadwick’s Discovery Mass of neutron = 1.67 x 10 -24 g (same as proton) Charge = no charge

5. Atomic Number This is the number of protons in an atom Hydrogen has 1 proton and thus is atomic number 1 Oxygen has 8 protons and thus atomic number 8 Every element is different due to its different numbers of protons So changing the number of protons changes the element! – Some elements may have the same electrons (ions) or the same neutrons (isotopes)

6. Atomic Number The atomic number is found on the bottom left corner Atomic mass on the top left corner Symbol in the middle

7. Atomic Number Electrons counterbalance the charge of protons – So the number of electrons in a neutral atom is the same as the number of protons When an electron is removed from a neutral atom – It becomes +ve because #protons > #electrons When electron is added to a neutral atom – It becomes –ve as #protons < #electrons Atoms with net charges are called ions – Net charge = #proton - #electron

8. Atomic Number We show an ion exist by putting a +/- number on the top right corner of our element NOTE! – Proton numbers do not change in ions

9. Atomic Number You try! Find the number of protons and electrons of the following – Uranium – Thallium – Tin – Lead – Mercury – Helium – Yttrium

10. Atomic Mass The mass of the atom Atomic mass = #neutron + #protons #neutron = atomic mass – atomic number Oxygen has an atomic mass of 16. It has an atomic number of 8. To find the #neutron, we subtract the two. – 16-8 = 8 neutrons Gold’s atomic mass is 197 and atomic number is 79 – #neutron = 197 – 79 = 118 neutrons

11. Atomic Mass The electron is so light, it is only 1/1836 the mass of a proton and neutron that it does not contribute to the mass of the atom We base all our atomic masses on the mass of carbon-12. The 12 stands for its atomic mass of 12.0000g/mol or amu (atomic mass unit) 1 amu = 1.67 x 10 -24 g or the same mass as a neutron and proton

12. Atomic Mass You try, find the number of neutrons of the following. As well, what is the number of protons and electrons? – Plutonium – Einsteinium – Thorium – Gallium – Germanium – Californium

13. Practice time!

14. Isotopes As with ions, which is when we have different numbers of electrons An isotope is where the number of neutron is different Isotopes still have the same number of protons as the original atom As they have different atomic masses due to the different number of neutrons, we write their names different.

15. Isotopes We write the names with a hyphen and their mass Carbon-12 = regular 12 amu carbon Carbon-13 = carbon with 1 extra neutron Carbon-14 = carbon with 2 extra neutrons

16. Isotopes When writing them in chemical symbol format, we drop the atomic number and just write the mass 16 O and 18 O 35 Cl and 37 Cl

17. Isotopes Lets take a look at hydrogen and its isotopes Hydrogen-1 (protium) – 99.985% of all hydrogen atoms – Most common element in our universe – Has 1 proton and o neutrons Hydrogen-2 (deuterium) – Has 1 proton and 1 neutron – 0.0167% of all hydrogen atoms – Used in nuclear reactors as heavy water D 2 O Hydrogen-3 (tritium) – Has 1 proton and 2 neutrons – Used in hydrogen bombs

18. Isotopes We can find the number of protons, neutrons, and electrons of an isotope as we would with a standard atom. – Just have to note the mass and that mass change is due to neutrons

19. Isotopes You try finding the number of protons, neutrons, and electrons with the following – Uranium-238 – Oxygen-18 – Xenon-126 – Hafnium-180

20. Average Atomic Mass Why are all the masses of elements not whole numbers? Why isn’t carbon 12.0000 and oxygen 16.00000 and chlorine just 35.00000 or 36.00000? This is due to the masses in the periodic table being averages of all the masses of the isotopes based on abundance

21. Example Carbon-12 is 98.9% abundant in nature Carbon-13 is 1.1% abundant in nature

22. Average Atomic Mass Steps to solve Multiply each percentage as a decimal with the atomic mass Add up all your decimals This is your average atomic mass that shows up on the periodic table

23. Example Carbon-12 is 98.9% abundant in nature Carbon-13 is 1.1% abundant in nature

24. Example Nitrogen has an average atomic mass of 14.007. The two isotopes that make up nitrogen are nitrogen-14 and nitrogen-15. What are the percent abundance of each isotope?

25. Average Atomic Mass You try – Chlorine is 75.8% chlorine-35 and 24.2% chlorine- 37. What is the average atomic mass of chlorine?

26. Electron Arrangements We look at electron arrangements in the form of Bohr models

27. Electron Arrangements Each of the noble gases outer shells are full – They satisfy the octet rule Outer shell electrons are also called “valence electrons” – Hence why the outer shell is usually called the valence shell A full outer shell is stable, it doesn’t want to give or receive any more electrons

28. Remember! 1 st Shell = 2 electrons 2 nd Shell = 8 electrons 3 rd Shell = 8 electrons 4 th Shell = 18 electrons ----------------------------------------------------------- 5 th Shell = 18 electrons 6 th shell = 32 electrons 7 th shell = 32 electrons

29. Remember! You can remember this by counting across the periodic table. The first row has 2 elements so 2 electrons The second row has 8 elements so 8 electrons and so forth!

30. How do other elements gain stability? Other elements do not have full outer shells as the noble gases do They will try to lose or gain electrons to get to a full outer shell

32. How can we tell which will lose or gain electrons?

34. Carbon stability?

35. Summary of element stability

36. Why does an element want to gain or lose electrons anyways? Every element has an affinity for electrons – Affinity = attraction Some elements have more affinity than others We measure affinity and call it electronegativity The higher the electronegativity, the more the element wants electrons – Fluorine has the highest electronegativity – Highest top right and weak bottom left

37. So how does it work? When two elements with differences in electronegativity come together, the one that is more electronegative draws the electron away from the less electronegative element

38. vs

39. Homework Page 146 #13-17 Page 147 #19 Page 149 #22 Page 150 #23 and 25 Worksheet on isotopes Worksheet on atomic number