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Chapter 3 Atoms: The Building Blocks of Matter. The Atomic Theory  Law of conservation of mass  Mass is neither destroyed nor created  Law of definite.

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Presentation on theme: "Chapter 3 Atoms: The Building Blocks of Matter. The Atomic Theory  Law of conservation of mass  Mass is neither destroyed nor created  Law of definite."— Presentation transcript:

1 Chapter 3 Atoms: The Building Blocks of Matter

2 The Atomic Theory  Law of conservation of mass  Mass is neither destroyed nor created  Law of definite proportions  Compound is always composed of same proportion of elements  Law of multiple proportions  If two different compounds are composed of the same elements, the two elements form a ratio of small number  Law of conservation of mass  Mass is neither destroyed nor created  Law of definite proportions  Compound is always composed of same proportion of elements  Law of multiple proportions  If two different compounds are composed of the same elements, the two elements form a ratio of small number

3 Law of Conservation of Mass

4 Law of Multiple Proportions

5 Dalton  All matter is composed of atoms  Atoms of an element are identical in size, mass and other properties  Atoms cannot be subdivided, created, or destroyed  Atoms combine in simple whole-number ratios  Atoms are combined, separated, or rearranged in chemical reactions  All matter is composed of atoms  Atoms of an element are identical in size, mass and other properties  Atoms cannot be subdivided, created, or destroyed  Atoms combine in simple whole-number ratios  Atoms are combined, separated, or rearranged in chemical reactions

6 Modern Atomic Theory  All matter is composed of atoms  Atoms of one element differ in properties from atoms of another element  Atom - smallest particle of an element that retains the chemical properties of that element  All matter is composed of atoms  Atoms of one element differ in properties from atoms of another element  Atom - smallest particle of an element that retains the chemical properties of that element

7 Thompson  Current passed through cathode-ray tube  Current produced a stream of particles (cathode ray) that traveled towards the anode  Rays deflected from negatively charged object  Ratio of charge to mass of particles  Current passed through cathode-ray tube  Current produced a stream of particles (cathode ray) that traveled towards the anode  Rays deflected from negatively charged object  Ratio of charge to mass of particles

8 Milikan  Oil-drop experiment  Charge of electron determined  Calculated mass of electron using ratio of charge to mass  Oil-drop experiment  Charge of electron determined  Calculated mass of electron using ratio of charge to mass

9 The Electron  Mass of 9.109 x 10 -31 kg  Atoms are neutral, so must contain same number of electrons and protons  Electrons mass has negligible effect on total mass of atom  Mass of 9.109 x 10 -31 kg  Atoms are neutral, so must contain same number of electrons and protons  Electrons mass has negligible effect on total mass of atom

10 The Nucleus  Rutherford’s gold foil experiment  Thin, gold foil bombarded with  particles  Some  particles deflected  Caused by positively charged nucleus  Volume of nucleus small  Rutherford’s gold foil experiment  Thin, gold foil bombarded with  particles  Some  particles deflected  Caused by positively charged nucleus  Volume of nucleus small

11 Rutherford

12

13 The Nucleus  Composed of two particles  Protons  Neutrons  Protons mass = 1.673 x 10 -27 kg  1826 times greater than e -  Nuclear strong force  Holds positive particles together  Composed of two particles  Protons  Neutrons  Protons mass = 1.673 x 10 -27 kg  1826 times greater than e -  Nuclear strong force  Holds positive particles together

14 Atomic Number  Atoms of different elements have different number of protons  Atomic number (Z)  number of protons in the nucleus  Elements arranged in order of their atomic number on periodic table  Atoms of different elements have different number of protons  Atomic number (Z)  number of protons in the nucleus  Elements arranged in order of their atomic number on periodic table

15 Mass Number  Total number of protons and neutrons  Ex.Hydrogen Isotopes  Total number of protons and neutrons  Ex.Hydrogen Isotopes

16 Isotopes  Element may contain different number of neutrons  Isotopes have differing mass  Naming  Helium-4 (hyphen notation)  4 2 Helium (nuclear symbol)  Element may contain different number of neutrons  Isotopes have differing mass  Naming  Helium-4 (hyphen notation)  4 2 Helium (nuclear symbol)

17 Problems  How many protons, electrons, and neutrons are in an atom of carbon-13?  Write the nuclear symbol for oxygen- 16.  How many protons, electrons, and neutrons are in an atom of bromine-80?  Write the nuclear symbol for carbon-13.  Write the hyphen notation for the element that contains 15 electrons and 15 neutrons.  How many protons, electrons, and neutrons are in an atom of carbon-13?  Write the nuclear symbol for oxygen- 16.  How many protons, electrons, and neutrons are in an atom of bromine-80?  Write the nuclear symbol for carbon-13.  Write the hyphen notation for the element that contains 15 electrons and 15 neutrons.

18 Relative Atomic Masses  Atomic mass unit (amu)  1/12 the mass of carbon-12  1.660 540 x 10 -27 kg  Hydrogen-1 = 1 amu  Average atomic mass  Weighted average of atomic masses of isotopes  Atomic mass unit (amu)  1/12 the mass of carbon-12  1.660 540 x 10 -27 kg  Hydrogen-1 = 1 amu  Average atomic mass  Weighted average of atomic masses of isotopes

19 Average Atomic Mass  Ex.  25% weigh 2.00 g  75% weigh 3.00 g  (2.00 g x 0.25) + (3.00 g x 0.75) = 2.75 g  Ex.  25% weigh 2.00 g  75% weigh 3.00 g  (2.00 g x 0.25) + (3.00 g x 0.75) = 2.75 g

20 Problem  What is the average atomic mass of copper which consists of 69.17% copper-63 (62.929 598 amu), and copper-65 (64.927 793 amu)?

21 Problems  Three isotopes of argon occur in nature - Ar-36, Ar-38, Ar-40. Calculate the average atomic mass of argon to two decimal places, given the following relative atomic masses and abundances of each of the isotopes: argon-36 (35.97 amu; 0.337%), argon-38 (37.96 amu; 0.063%), and argon-40 (39.96 amu; 99.600%).

22 The Mole  Amount of substance that contains as many particles as there are atoms in exactly 12 g of carbon-12  Counting unit like dozen  Dozen = 12  Mole = 6.022 x 10 23  Avogadro’s number  6.022 x 10 23  Amount of substance that contains as many particles as there are atoms in exactly 12 g of carbon-12  Counting unit like dozen  Dozen = 12  Mole = 6.022 x 10 23  Avogadro’s number  6.022 x 10 23

23 Molar Mass  Mass of one mole of pure substance  Units → g/mol  Molar mass = atomic mass in amu  Mass of one mole of pure substance  Units → g/mol  Molar mass = atomic mass in amu

24 Conversions

25  1 mol/(6.022 x 10 23 ) atoms  Molar mass/mol  1 mol/(6.022 x 10 23 ) atoms  Molar mass/mol

26 Problems  What is the mass in grams of 3.6 mol of the element carbon, C?  What is the mass in grams of 0.733 mol of the element chlorine, Cl?  How many moles of copper, Cu, are in 3.22 g of copper?  How many moles of lithium, Li, are in 2.72 x 10 -4 g of lithium?  What is the mass in grams of 3.6 mol of the element carbon, C?  What is the mass in grams of 0.733 mol of the element chlorine, Cl?  How many moles of copper, Cu, are in 3.22 g of copper?  How many moles of lithium, Li, are in 2.72 x 10 -4 g of lithium?

27 Problems  How many moles of carbon, C, are in 2.25 x 10 22 atoms of carbon?  How many moles of oxygen, O are in 2 000 000 atoms of oxygen?  How many atoms of sodium, Na, are in 3.80 mol of sodium?  What is the mass in grams of 5.0 x 10 9 atoms of neon, Ne?  How many moles of carbon, C, are in 2.25 x 10 22 atoms of carbon?  How many moles of oxygen, O are in 2 000 000 atoms of oxygen?  How many atoms of sodium, Na, are in 3.80 mol of sodium?  What is the mass in grams of 5.0 x 10 9 atoms of neon, Ne?

28 Problems  How many atoms of carbon, C, are in 0.020 g of carbon?  What mass of silver, Ag, contains the same number of atoms as 10.0 g of boron, B?  How many moles of CO 2 are in 66.0 g of dry ice, which is solid CO 2  How many atoms of carbon, C, are in 0.020 g of carbon?  What mass of silver, Ag, contains the same number of atoms as 10.0 g of boron, B?  How many moles of CO 2 are in 66.0 g of dry ice, which is solid CO 2

29 Chapter Review  Pg. 89  1, 8, 11, 17, 18acd, 20, 21, 22ade, 23abcd  Pg. 89  1, 8, 11, 17, 18acd, 20, 21, 22ade, 23abcd


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