new chm 151_unit_2_power_points.sp13
TRANSCRIPT
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The Components of Matter
Chapter 2
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Chapter 2: The Components of Matter
2.1 Elements, Compounds, and Mixtures:
An Atomic Overview
2.2 The Observations That Led to an Atomic View of Matter
2.3 Dalton’s Atomic Theory
2.4 The Observations That Led to the Nuclear Atom Model
2.5 The Atomic Theory Today
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Chapter 2: The Components of Matter
2.6 Elements: A First Look at the Periodic Table
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Atoms, Molecules and Ions
• Dalton’s Atomic Theory• Atomic Structure• Atomic Mass• Chemical Formulas• Chapters 2.1-2.5, 3.1 (Silberberg)
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Goals & Objectives
• The student will understand the characteristics of the three types of matter: elements, compounds, and mixtures. (2.1)
• The student will understand the significance of the three mass laws: conservation of mass, definite composition and multiple proportions. (2.2)
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Goals & Objectives
• The student will understand the postulates of Dalton’s atomic theory and how it explains the mass laws. (2.3)
• The student will understand the major contributions of experiments by Thomson, Millikan, and Rutherford concerning the atomic structure. (2.4)
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Goals & Objectives
• The student will understand the structure of the atom along with the characteristics of the proton, neutron, and electron and the importance of isotopes. (2.5)
• The student will understand the meaning and usefulness of the mole. (3.1)
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Goals & Objectives
• The student will understand the relationship between the formula mass and molar mass. (3.1)
• The student will understand the relationship among the amount of substance (in moles), mass (in grams), and the number of chemical atoms. (3.1)
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Goals & Objectives
• The student will understand the information in a chemical formula. (3.1)
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Master these Skills
• Distinguish between elements, compounds and mixtures at the atomic scale. (SP 2.1)
• Using the mass ratio of an element to a compound to find the mass of an element in a compound. (SP 2.2)
• Visualizing the mass laws. (SP 2.3)
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Master these Skills
• Using atomic notation to express the subatomic makeup of an isotope. (SP 2.4)
• Calculating an atomic mass from isotopic composition. (SP 2.5)
• Calculating the molar mass of any substance. (3.1; SP 3.3 and 3.4)
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Master these Skills
• Converting between amount of substance (in moles), mass (in grams), and the number of atoms. (SP 3.1-3.3)
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Matter
• A scheme for the classification of matter
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Definitions for Components of Matter
Element - the simplest type of substance with unique physical and
chemical properties. An element consists of only one type of atom. It
cannot be broken down into any simpler substances by physical or
chemical means.
Molecule - a structure that consists of two or
more atoms that are chemically bound together
and thus behaves as an independent unit.
Figure 2.1
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Compound - a substance
composed of two or more elements
which are chemically combined.
Mixture - a group of two or more
elements and/or compounds that
are physically intermingled.
Definitions for Components of Matter
Figure 2.1
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Table 2.1 Some Properties of Sodium, Chlorine, and Sodium Chloride.
Property Sodium + Chlorine Sodium Chloride
Melting point 97.8°C -101°C 801°C
Boiling point 881.4°C -34°C 1413°C
Color Silvery Yellow-green Colorless (white)
Density 0.97 g/cm3 0.0032 g/cm3 2.16 g/cm3
Behavior in water Reacts Dissolves slightly Dissolves freely
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Figure 2.2 The law of mass conservation.
The total mass of substances does not change during a chemical reaction.
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The total mass of substances present does not change during a chemical reaction.
reactant 1 + reactant 2
total mass
product
total mass=
calcium oxide + carbon dioxide calcium carbonate
CaO + CO2 CaCO3
56.08 g + 44.00 g 100.08 g
Law of Mass Conservation
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No matter the source, a particular compound is composed of the same elements in the same parts (fractions) by mass.
Law of Definite (or Constant) Composition
Figure 2.3
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Analysis by Mass(grams/20.0 g)
Mass Fraction(parts/1.00 part)
Percent by Mass(parts/100 parts)
8.0 g calcium2.4 g carbon9.6 g oxygen
20.0 g
40% calcium12% carbon48% oxygen
100% by mass
0.40 calcium0.12 carbon0.48 oxygen
1.00 part by mass
Calcium carbonate
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If elements A and B react to form two compounds, the different masses of B that combine with a fixed mass of A can be expressed as a ratio of small whole numbers.
Example: Carbon Oxides A & B
Carbon Oxide II : 72.7% oxygen and 27.3% carbon
Law of Multiple Proportions
Carbon Oxide I : 57.1% oxygen and 42.9% carbon
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For oxide I: g O
g C=
57.1
42.9= 1.33
= g O
g C
72.7
27.3= 2.66
2.66 g O/g C in II
1.33 g O/g C in I=
2
1
Assume that you have 100 g of each compound.
In 100 g of each compound:
g O = 57.1 g for oxide I & 72.7 g for oxide
g C = 42.9 g for oxide I & 27.3 g for oxide II
For oxide II:
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Dalton’s Atomic Theory
Dalton postulated that:
1. All matter consists of atoms; tiny indivisible particles of an element that cannot be created or destroyed.
2. Atoms of one element cannot be converted into atoms of another element.
3. Atoms of an element are identical in mass and other properties and are different from the atoms of any other element.
4. Compounds result from the chemical combination of a specific ratio of atoms of different elements.
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Dalton’s Atomic Theory
explains the mass laws
Mass conservation
Atoms cannot be created or destroyed
or converted into other types of atoms.
postulate 1
postulate 2
Since every atom has a fixed mass,
during a chemical reaction the same atoms are present but in different combinations; therefore there is no mass change overall.
postulate 3
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Definite composition
Atoms are combined in compounds in specific ratios
and each atom has a specific mass.
Each element constitutes a fixed fraction of the total mass in a compound.
postulate 3
postulate 4
Dalton’s Atomic Theory
explains the mass laws
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Multiple proportions
Atoms of an element have the same mass
and atoms are indivisible.
When different numbers of atoms of elements combine, they must do so in ratios of small, whole numbers.
postulate 3
postulate 1
Dalton’s Atomic Theory
explains the mass laws
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The Structure of the Atom
• Fundamental Particles in Atoms• Particle Mass(amu) Charge• electron 0.00054858 -1• proton 1.0073 +1• neutron 1.0087 0
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The Structure of the Atom
• Electrons
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Figure 2.4
Observations that established the properties of cathode rays.
Observation Conclusion
Ray bends in magnetic field. Ray consists of charged particles.
Ray bends toward positive plate in electric field.
Ray consists of negative particles.
Ray is identical for any cathode. These particles are found in ALL matter.
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Figure 2.5 Millikan’s oil-drop experiment for measuring an electron’s charge.
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Millikan’s findings were used to calculate the mass on an electron.
mass of electron = xmass
chargecharge
= (-5.686x10-12 kg/C) x (-1.602x10-19 C)
determined by J.J. Thomson and others
= 9.109x10-31 kg = 9.109x10-28 g
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Figure 2.6 Rutherford’s a-scattering experiment and discovery of the atomic nucleus.
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Figure 2.7 General features of the atom.
The atom is an electrically neutral, spherical entity composed of a positively charged central nucleus surrounded by one or more negatively charged electrons.
The atomic nucleus consists of protons and neutrons.
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Charge Mass
Name (Symbol)
Relative Absolute (C)* Relative (amu)†
Absolute (g) Location in Atom
Proton(p+)
1+ +1.60218x10-19 1.00727 1.67262x10-24 Nucleus
Neutron(n0)
0 0 1.00866 1.67493x10-24 Nucleus
Electron(e-)
1- -1.60218x10-19 0.00054858 9.10939x10-24 Outside nucleus
Table 2.2 Properties of the Three Key Subatomic Particles
* The coulomb (C) is the SI unit of charge.
† The atomic mass unit (amu) equals 1.66054x10-24 g.
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The Modern Reassessment of the Atomic Theory
1. All matter is composed of atoms. The atom is the smallest body that retains the unique identity of the element.
2. Atoms of one element cannot be converted into atoms of another element in a chemical reaction. Elements can only be converted into other elements in nuclear reactions.
3. All atoms of an element have the same number of protons and electrons, which determines the chemical behavior of the element. Isotopes of an element differ in the number of neutrons, and thus in mass number. A sample of the element is treated as though its atoms have an average mass.
4. Compounds are formed by the chemical combination of two or more elements in specific ratios.
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Figure 2.8
Atomic Symbol, Number and Mass
X = Atomic symbol of the element
A = mass number; A = Z + N
Z = atomic number (the number of protons in the nucleus)
N = number of neutrons in the nucleus
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Figure 2.8
Isotopes
Isotopes are atoms of an element with the same number of protons, but a different number of neutrons.
Isotopes have the same atomic number, but a different mass number.
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Sample Problem 2.4 Determining the Number of Subatomic Particles in the Isotopes of an Element
PROBLEM: Silicon (Si) has three naturally occurring isotopes: 28Si, 29Si, and 30Si. Determine the number of protons, neutrons, and electrons in each silicon isotope.
PLAN: The mass number (A) is given for each isotope and is equal to the number of protons + neutrons. The atomic number Z, found on the periodic table, equals the number of protons.The number of neutrons = A – Z, and the number of electrons equals the number of protons for a neutral atom.
SOLUTION: The atomic number of silicon is 14; therefore
28Si has 14p+, 14e- and 14n0 (28-14)
29Si has 14p+, 14e- and 15n0 (29-14)
30Si has 14p+, 14e- and 16n0 (30-14)
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Figure B2.1
Tools of the Laboratory
Formation of a positively charged neon particle (Ne+).
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Figure B2.2
Tools of the Laboratory
The mass spectrometer and its data.
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Isotopes and Neutrons
• atoms of the same element having different atomic mass numbers
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The Complete Symbol
• Competency III-1• M
ZX where– M = atomic mass number(p + n)
–Z = atomic number (p)
– = electrons in a neutral atom
• Number of neutrons = M - Z
• 73Li p =___ e =____ n =____
• 7434Se p = ____ e = ____ n = ___
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Ions
• Charged atoms obtained by adding or removing electrons to an atom.
• Cations-positively charged ions• Anions-negatively charged ions
• 3919K+ p = ___ e = ___ n = ___
• 3216S-2 p = ___ e = ___ n = ___
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Atomic Weights(Masses)
• a relative scale based upon 126C having a
mass of exactly 12 amu (atomic mass units)
• The atomic weight of an element is the weighted average of all the isotopes of that element.
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Sample Problem 2.5 Calculating the Atomic Mass of an Element
PLAN: Find the weighted average of the isotopic masses.
PROBLEM: Silver (Ag, Z = 47) has two naturally occurring isotopes, 107Ag and 109Ag. From the mass spectrometric data provided, calculate the atomic mass of Ag.
Isotope Mass (amu) Abundance (%)107Ag109Ag
106.90509
108.90476
51.84
48.16
add isotopic portions
multiply by fractional abundance of each isotope
mass (g) of each isotope
portion of atomic mass from each isotope
atomic mass
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SOLUTION:
mass portion from 107Ag = 106.90509 amu x 0.5184 = 55.42 amu
mass portion from 109Ag = 108.90476amu x 0.4816 = 52.45amu
atomic mass of Ag = 55.42amu + 52.45amu
Sample Problem 2.5
= 107.87amu
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Atomic Weights(Masses)
• Naturally occurring copper consists of two isotopes. It is 69.1% 63
29Cu which has a mass of 62.9 amu and 30.9% 65
29Cu which has a mass of 64.9 amu. Determine the atomic weight of copper.
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Atomic Weights(Masses)
• Naturally occurring chromium consists of four isotopes. It is
4.31% chromium-50 ,mass = 49.946amu, 83.76% chromium-52, mass = 51.941amu, 9.55% chromium 53, mass = 52.941amu 2.38% chromium 54, mass = 53.939amu.
Determine the atomic mass of chromium.
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Atomic Masses (Weights)
• Element Atomic Weight• H2 2.0158 amu
• N2 28.0134 amu
• Mg 24.3050 amu
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The mole (mol) is the amount of a substance that contains the same number of entities as there are atoms in exactly 12 g of carbon-12.
One mole (1 mol) contains 6.022x1023 entities (to four significant figures). This number is called Avogadro’s number and is abbreviated as N.
The Mole
The term “entities” refers to atoms, ions, molecules, formula units, or electrons – in fact, any type of particle.
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The Mole
• One mole is defined as 6.022 x 1023 objects. Also called Avagadro’s number.
• The mass of one mole of an element will be its atomic mass expressed in grams.
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One mole (6.022x1023 entities) of some familiar substances.
Figure 3.1
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The Mole
• Element Mass Contains Atoms
• Pt 195.1 g 6.022 x 1023
• Au 197.0 g 6.022 x 1023
• Pb 207.2 g 6.022 x 1023
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12 red marbles @ 7g each = 84g12 yellow marbles @4g each = 48g 55.85g Fe = 6.022 x 1023 atoms Fe
32.07g S = 6.022 x 1023 atoms S
Figure 3.1
Counting objects of fixed relative mass.
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Water 18.02 gCaCO3
100.09 g
Oxygen 32.00 g
Copper 63.55 g
One mole of common substances.
Figure 3.2
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Table 3.1 Information Contained in the Chemical Formula of Glucose C6H12O6 ( M = 180.16 g/mol)
Carbon (C) Hydrogen (H) Oxygen (O)
Atoms/molecule of compound
6 atoms 12 atoms 6 atoms
Moles of atoms/mole of compound
6 mol of atoms 12 mol of atoms 6 mol of atoms
Atoms/mole of compound
6(6.022x1023) atoms 12(6.022x1023) atoms 6(6.022x1023) atoms
Mass/molecule of compound
6(12.01 amu) = 72.06 amu
12(1.008 amu) = 12.10 amu
6(16.00 amu) = 96.00 amu
Mass/mole of compound
72.06 g 12.10 g 96.00 g
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Interconverting Moles, Mass, and Number of Chemical Entities
Mass (g) = no. of moles x no. of grams
1 mol
No. of moles = mass (g) xno. of grams
1 mol
No. of entities = no. of moles x6.022x1023 entities
1 mol
No. of moles = no. of entities x 6.022x1023 entities
1 mol
g
M
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Mass-mole-number relationships for elements.Figure 3.2
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Sample Problem 3.1 Calculating the Mass of a Given Amount of an Element
PROBLEM:
SOLUTION:
amount (mol) of Ag
mass (g) of Ag
Silver (Ag) is used in jewelry and tableware but no longer in U.S. coins. How many grams of Ag are in 0.0342 mol of Ag?
PLAN: To convert mol of Ag to mass of Ag in g we need the molar mass of Ag.
multiply by M of Ag (107.9 g/mol)
0.0342 mol Ag x1 mol Ag
107.9 g Ag= 3.69 g Ag
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Sample Problem 3.2 Calculating the Number of Entities in a Given Amount of an Element
PROBLEM: Gallium (Ga) is a key element in solar panels, calculators and other light-sensitive electronic devices. How many Ga atoms are in 2.85 x 10-3 mol of gallium?
To convert mol of Ga to number of Ga atoms we need to use Avogadro’s number.
PLAN:
mol of Ga
atoms of Ga
multiply by 6.022x1023 atoms/mol
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SOLUTION:
2.85 x 10-3 mol Ga atoms x 6.022x1023 Ga atoms
1 mol Ga atoms
= 1.72 x 1021 Ga atoms
Sample Problem 3.2
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Sample Problem 3.3 Calculating the Number of Entities in a Given Mass of an Element
PROBLEM: Iron (Fe) is the main component of steel and is therefore the most important metal in society; it is also essential in the body. How many Fe atoms are in 95.8 g of Fe?
The number of atoms cannot be calculated directly from the mass. We must first determine the number of moles of Fe atoms in the sample and then use Avogadro’s number.
PLAN:
mass (g) of Fe
amount (mol) of Fe
atoms of Fe
divide by M of Fe (55.85 g/mol)
multiply by 6.022x1023 atoms/mol
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95.8 g Fe x
SOLUTION:
55.85 g Fe
1 mol Fe= 1.72 mol Fe
1.72 mol Fe x 6.022x1023 atoms Fe
1 mol Fe
= 1.04 x 1024 atoms Fe
Sample Problem 3.3
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Amount-mass-number relationships for compounds.Figure 3.3
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Examples
• Competency I-2• Determine the number of moles in 73.4g
of Mg• Calculate the number of atoms in 5.00
moles of magnesium.• Determine the mass of a Mg atom in
grams to three significant figures.
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Molar Masses
• The molar mass of a substance is the sum of the atomic masses of the atoms of each element in the formula.
• Determine the molar mass of propane (C3H8).
• How many molecules are present in 44.1 g of propane?
• Determine the number of molecules of C3H8 in 74.6 grams of propane.
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Sample Problem 3.4 Calculating the Number of Chemical Entities in a Given Mass of a Compound I
PROBLEM: Nitrogen dioxide is a component of urban smog that forms from the gases in car exhausts. How many molecules are in 8.92 g of nitrogen dioxide?
number of NO2 molecules
PLAN: Write the formula for the compound and calculate its molar mass. Use the given mass to calculate first the number of moles and then the number of molecules.
divide by M
multiply by 6.022 x 1023 formula units/mol
mass (g) of NO2
amount (mol) of NO2
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SOLUTION: NO2 is the formula for nitrogen dioxide.
M = (1 x M of N) + (2 x M of O) = 14.01 g/mol + 2(16.00 g/mol) = 46.01 g/mol
8.92 g NO2 x
= 1.17 x 1023 molecules NO2
1 mol NO2
46.01 g NO2
6.022x1023 molecules NO2
1 mol NO2
= 0.194 mol NO2
0.194 mol NO2 x
Sample Problem 3.4
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Sample Problem 3.5 Calculating the Number of Chemical Entities in a Given Mass of a Compound II
PLAN:
PROBLEM: Ammonium carbonate, a white solid that decomposes on warming, is an component of baking powder.
a) How many formula units are in 41.6 g of ammonium carbonate?
b) How many O atoms are in this sample?
Write the formula for the compound and calculate its molar mass. Use the given mass to calculate first the number of moles and then the number of formula units.The number of O atoms can be determined using the formula and the number of formula units.
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number of (NH4)2CO3 formula units
mass (g) of (NH4)2CO3
amount (mol) of (NH4)2CO3
SOLUTION: (NH4)2CO3 is the formula for ammonium carbonate.
M = (2 x M of N) + (8 x M of H) + (1 x M of C) + (3 x M of O) = (2 x 14.01 g/mol) + (8 x 1.008 g/mol) + (12.01 g/mol) + (3 x 16.00 g/mol)
= 96.09 g/mol
divide by M
multiply by 6.022 x 1023 formula units/mol
number of O atoms
3 O atoms per formula unit of (NH4)2CO3
Sample Problem 3.5
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41.6 g (NH4)2CO3 x
= 2.61x1023 formula units (NH4)2CO3
1 mol (NH4)2CO3
96.09 g (NH4)2CO3
6.022x1023 formula units (NH4)2CO3
1 mol (NH4)2CO3
= 0.433 mol (NH4)2CO3
0.433 mol (NH4)2CO3 x
2.61x1023 formula units (NH4)2CO3 x 3 O atoms
1 formula unit of (NH4)2CO3
= 7.83 x 1023 O atoms
Sample Problem 3.5
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The molar mass (M) of a substance is the mass per mole of its entites (atoms, molecules or formula units).
For monatomic elements, the molar mass is the same as the atomic mass in grams per mole. The atomic mass is simply read from the Periodic Table.The molar mass of Ne = 20.18 g/mol.
Molar Mass
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For molecular elements and for compounds, the formula is needed to determine the molar mass.
The molar mass of O2 = 2 x M of O = 2 x 16.00 = 32.00 g/mol
The molar mass of SO2 = 1 x M of S + 2 x M of O = 32.00 + 2(16.00)
= 64.00 g/mol
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Molecular Masses from Chemical Formulas
Molecular mass = sum of atomic masses
For the H2O molecule:
molecular mass =
(2 x atomic mass of H) + (1 x atomic mass of O)
= (2 x 1.008 amu) + (1 x 16.00 amu)
= 18.02 amu
For ionic compounds we refer to a formula mass since ionic compounds do not consist of molecules.
By convention, we read masses off the periodic table to 4 significant figures.
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Sample Problem 2.15 Calculating the Molecular Mass of a Compound
SOLUTION:
(a) tetraphosphorous trisulfide (b) ammonium nitrate
PROBLEM: Using the periodic table, calculate the molecular (or formula) mass of:
PLAN: Write the formula and then multiply the number of atoms by the respective atomic masses. Add the masses for each compound.
(a) P4S3
molecular mass = (4 x atomic mass of P) + (3 x atomic mass of S) = (4 x 30.97 amu) + (3 x 32.07 amu) = 220.09 amu
(b) NH4NO3
formula mass = (2 x atomic mass of N) + (4 x atomic mass of H) + (3 x atomic mass of O)
= (2 x 14.01 amu) + (4 x 1.008 amu) + (3 x 16.00 amu) = 80.05 amu
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Sample Problem 2.15 Calculating the Molecular Mass of a Compound
SOLUTION:
(a) tetraphosphorous trisulfide (b) ammonium nitrate
PROBLEM: Using the periodic table, calculate the molecular (or formula) mass of:
PLAN: Write the formula and then multiply the number of atoms by the respective atomic masses. Add the masses for each compound.
(a) P4S3
molecular mass = (4 x atomic mass of P) + (3 x atomic mass of S) = (4 x 30.97 amu) + (3 x 32.07 amu) = 220.09 amu
(b) NH4NO3
formula mass = (2 x atomic mass of N) + (4 x atomic mass of H) + (3 x atomic mass of O)
= (2 x 14.01 amu) + (4 x 1.008 amu) + (3 x 16.00 amu) = 80.05 amu
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Molar Masses
• Determine the number of (a) moles, (b) molecules, and (c) oxygen atoms in 60.0 g of ozone, O3.
• Determine the molar masses of Ca(NO3)2.
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Filtration: Separates components of a mixture based upon differences in particle size. Filtration usually involves separating a precipitate from solution.
Crystallization: Separation is based upon differences in solubility of components in a mixture.
Distillation: separation is based upon differences in volatility.
Extraction: Separation is based upon differences in solubility in different solvents (major material).
Chromatography: Separation is based upon differences in solubility in a solvent versus a stationary phase.
Basic Separation Techniques
Tools of the Laboratory
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Figure B2.3
Tools of the Laboratory
Distillation
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Figure B2.4
Tools of the Laboratory
Procedure for column chromatography
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Figure B2.5
Tools of the Laboratory
Principle of gas-liquid chromatography (GLC).