2. Dalton’s Atomic Theory
Law of conservation of mass
Law of multiple proportions

3. Law of Conservation of Mass
Figure 2.5 | A representation of combining gases at the molecular level. The spheres represent atoms in the molecules.
Law of Conservation of Mass
LLa
Figure 2-5 p50

4. Dalton’s Atomic Theory Law of Multiple Proportions2
Law of Multiple Proportions

5. The Structure of the Atom
Dalton’s atomic theory
atom, the basic unit of element
However, atom has subatomic particles
-Electrons, neutrons, protons
Electrons
-negative charge
-negligible mass
Dalton imagined an atom that was both extremely small and indivisible. But later in the 19th century and the beginning of the 20th century, study of subatomic particles were done and three such particles-electrons, protons, and neutrons were discovered.
Discovery of electron: Cathode ray tube, cathode (-)and anode (+) connected to high voltage. Cathode emits an invisible ray drawn to anode and strikes a specially coated surface producing fluorescence. Reacted different ways with magenetic and electric fields. Finally figured out this to be negatively charged particle called electron.
J.J. Thompson and Millikan found the charge and mass of an electron.
Next slide shows the size of atom and nucleus. Atoms are relatively “fuzzy” do not have well defined boundaries.
H – 1 proton ,mass 1
He-2protons, mass 4, should be 2.
Led to the discovery of neutrons
H has no neutrons-the only one element like that.
He has 2 neutrons, almost the same mass as neutrons, so total mass is 4.

6. The Structure of the Atom (cont.)
Atom is neutral
Nucleus-a dense central core of the atom
Protons
-positive charge
mass is 1840 times the mass of electron
Neutrons
-electrically neutral
- Mass almost the same as proton
Atoms are electrically neutral, so it needs a +ve charge particle in equal number. Later Rutherford use alpha particles to probe the structure of atoms.

7. Atomic Number, Mass Number, and Isotopes
Atomic number (Z) = number of protons in a neutral atom
#protons = # of electrons (in a neutral atom)
Mass number (A) = number of protons (Z) + number of neutrons
Number of neutrons = A-Z
Chemical identity solely depend on the atomic number. For example, in the universe every atom which contains 9 protons is Fluorine.
Show the periodic Table and ask about different elements. Atomic number is the number on the top of the element.
In the periodic Table, it is the atomic weight, average of the mass of different isotopes.
Ask different elements in the periodic table –No. of protons, neutrons, and electrons.

8. Ernest Rutherford (1911) Explained the nuclear atom.
The atom has a dense center of positive charge called the nucleus.
Electrons travel around the nucleus at a large distance relative to the nucleus.
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9. (1908 Nobel Prize in Chemistry)
Rutherford’s Experiment
(1908 Nobel Prize in Chemistry)
Rutherford’s alpha scattering expt: Alpha particles (positive) went through thin foils of gold.- undeflected, slightly deflected, deflected, and bounced back.
(+) charge is concentrated in the nucleus, which is a dense central core within the atom. Most of the atom must have empty space. This explain all the different types of deflection.
particle velocity ~ 1.4 x 107 m/s
(~5% speed of light)
atoms positive charge is concentrated in the nucleus
proton (p) has opposite (+) charge of electron (-)
mass of p is 1840 x mass of e- (1.67 x g)

10. Cathode-Ray Tube (J.J. Thompson) Discovery of electron and Millikan with oil drop experiment determined the charge/mass of an electron (negligible) M
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11. Three types of radioactive emission exist:
Henri Becquerel (1896)
Discovered radioactivity by observing the spontaneous emission of radiation by uranium.
Three types of radioactive emission exist:
Gamma rays (ϒ) – high energy light
Beta particles (β) – a high speed electron
Alpha particles (α) – a particle with a 2+ charge
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12. Radioactivity is spontaneous emission of particles and /or radiation
Radioactivity is spontaneous emission of particles and /or radiation. Marie Curie, Rontgen, Becquerrel are involved in the discovery. You can see all these names in the radioactive units.
Alpha, +ve. Like He atom equivalen t to 2 protons, deflected by +vely charged particle
Beta, -ve, like electron, deflected by negativecharge
Gamma, no charge, penetreates through matter
Radioactivity is spontaneous emission of particles and /or radiation

13. Small compared with the overall size of the atom.
The nucleus is:
Small compared with the overall size of the atom.
Extremely dense; accounts for almost all of the atom’s mass.
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14. Nuclear Atom Viewed in Cross Section
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15. In nature most elements contain mixtures of isotopes.
Atoms with the same number of protons but different numbers of neutrons.
Show almost identical chemical properties; chemistry of atom is due to its electrons.
In nature most elements contain mixtures of isotopes.
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16. Two Isotopes of Sodium
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17. Isotopes are identified by: Atomic Number (Z) – number of protons
Mass Number (A) – number of protons plus number of neutrons
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18. A certain isotope X contains 23 protons and 28 neutrons.
EXERCISE!
A certain isotope X contains 23 protons and 28 neutrons.
What is the mass number of this isotope?
Identify the element.
Mass Number = 51
Vanadium
The mass number is 51. Mass Number = # protons + # neutrons. Mass Number = = 51. The element is vanadium.
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19. Chemical Bonds Covalent Bonds
Bonds form between atoms by sharing electrons.
Resulting collection of atoms is called a molecule.
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21. Chemical Bonds Ionic Bonds
Bonds form due to force of attraction between oppositely charged ions.
Ion – atom or group of atoms that has a net positive or negative charge.
Cation – positive ion; lost electron(s).
Anion – negative ion; gained electron(s).
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22. Molecular vs Ionic Compounds
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23. A certain isotope X+ contains 54 electrons and 78 neutrons.
EXERCISE!
A certain isotope X+ contains 54 electrons and 78 neutrons.
What is the mass number of this isotope?
133
The mass number is 133. The plus charge in X+ means that the ion has lost an electron, therefore the number of protons is 55 (54+1). The ion is Cs+ with a mass number of 133 (55+78).
Note: Use the red box animation to assist in explaining how to solve the problem.
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24. CONCEPT CHECK!
Which of the following statements regarding Dalton’s atomic theory are still believed to be true?
Elements are made of tiny particles called atoms.
All atoms of a given element are identical. – (due to Isotopes)
A given compound always has the same relative
numbers and types of atoms.
IV. Atoms are indestructible. –(nuclear chemistry)
Statements I and III are true. Statement II is not true (due to isotopes and ions). Statement IV is not true (due to nuclear chemistry).
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25. The Periodic Table Metals vs. Nonmetals
Groups or Families – elements in the same vertical columns; have similar chemical properties
Periods – horizontal rows of elements
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26. The Periodic Table

27. Alkaline Earth Metals (2A)
Groups or Families
Table of common charges formed when creating ionic compounds.
Group or Family
Charge
Alkali Metals (1A) 1+
Alkaline Earth Metals (2A) 2+
Halogens (7A) 1–
Noble Gases (8A)
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28. Naming Compounds Binary Compounds Composed of two elements
Ionic and covalent compounds included
Binary Ionic Compounds
Metal—nonmetal
Binary Covalent Compounds
Nonmetal—nonmetal
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29. Binary Ionic Compounds (Type I)
1. The cation is always named first and the anion second. 2. A monatomic cation takes its name from the name of the parent element. 3. A monatomic anion is named by taking the root of the element name and adding –ide.
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30. Binary Ionic Compounds (Type I)
Examples:
KCl Potassium chloride
MgBr2 Magnesium bromide
CaO Calcium oxide
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31. Binary Ionic Compounds (Type II)
Metals in these compounds form more than one type of positive ion.
Charge on the metal ion must be specified.
Roman numeral indicates the charge of the metal cation.
Transition metal cations usually require a Roman numeral.
Elements that form only one cation do not need to be identified by a roman numeral.
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32. Binary Ionic Compounds (Type II)
Examples:
CuBr Copper(I) bromide
FeS Iron(II) sulfide
PbO2 Lead(IV) oxide
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33. Polyatomic Ions Must be memorized (see Table 2.5 on pg. 65 in text).
Examples of compounds containing polyatomic ions:
NaOH Sodium hydroxide
Mg(NO3)2 Magnesium nitrate
(NH4)2SO4 Ammonium sulfate
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34. Formation of Ionic Compounds
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35. Binary Covalent Compounds (Type III)
Formed between two nonmetals.
1. The first element in the formula is named first, using the full element name.
2. The second element is named as if it were an anion.
3. Prefixes are used to denote the numbers of atoms present.
4. The prefix mono- is never used for naming the first element.
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36. Prefixes Used to Indicate Number in Chemical Names
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37. Binary Covalent Compounds (Type III)
Examples:
CO2 Carbon dioxide
SF6 Sulfur hexafluoride
N2O4 Dinitrogen tetroxide
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38. Flowchart for Naming Binary Compounds
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39. Overall Strategy for Naming Chemical Compounds
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40. Acids
Acids can be recognized by the hydrogen that appears first in the formula—HCl.
Molecule with one or more H+ ions attached to an anion.
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41. Acids
If the anion does not contain oxygen, the acid is named with the prefix hydro– and the suffix –ic.
Examples:
HCl Hydrochloric acid
HCN Hydrocyanic acid
H2S Hydrosulfuric acid
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42. Acids If the anion does contain oxygen:
The suffix –ic is added to the root name if the anion name ends in –ate.
Examples:
HNO3 Nitric acid
H2SO4 Sulfuric acid
HC2H3O2 Acetic acid
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43. Acids If the anion does contain oxygen:
The suffix –ous is added to the root name if the anion name ends in –ite.
Examples:
HNO2 Nitrous acid
H2SO3 Sulfurous acid
HClO2 Chlorous acid
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44. Flowchart for Naming Acids
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45. Which of the following compounds is named incorrectly?
EXERCISE!
Which of the following compounds is named incorrectly?
KNO3 potassium nitrate
TiO2 titanium(II) oxide
Sn(OH)4 tin(IV) hydroxide
PBr5 phosphorus pentabromide
CaCrO4 calcium chromate
Ti charge should be 4. titanium (IV) oxide
The correct answer is “b”. The charge on oxygen is 2-. Since there are two oxygen atoms, the overall charge is 4-. Therefore, the charge on titanium must be 4+ (not 2+ as the Roman numeral indicates).
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