Upload
edward-arnold
View
216
Download
0
Tags:
Embed Size (px)
Citation preview
Plan for Wed, 24 Sept 08• Lecture
– Classifying and separating mixtures (1.9)– How do we know that there are atoms? (2.2)– Ok, there are atoms. What do they look like? (2.5)– Re-introducing the periodic table (2.6-7)– Chemical nomenclature (2.8)
• Make sure to read:– 2.3 (Dalton’s atomic theory)
• Sections you can skip:– 2.1 (early history of chemistry), 2.4 (early experiments
to characterize the atom)
Pure Substances vs MixturesPure substances cannot be separated into different components by physical means.
Mixtures can be separated into different components.
The unique properties of the components of a mixture can be used to separate the components.
Homogeneous vs Heterogeneous Mixtures
A Homogeneous Mixture is a mixture that has a uniform appearance and composition throughout
A Heterogeneous Mixture is a mixture in which you can identify the component parts just by looking at it
Homogeneous mixtures are often indistinguishable from pure substances on the macroscopic level. You have to consider an unknown sample on the molecular level to
determine if it is a mixture or pure substance.
Separation Techniques
• Since components in a mixture retain their identities, we can exploit the unique properties of the components to separate them.
• The more similar the properties are, the more difficult it is to separate the components.
Separation of Heterogeneous Mixtures...by particle size
Cacao beans grow in the jungles of equatorial countries, many of which are rather dangerous.
Before chocolate manufacturers can roast the cacao beans from their suppliers, they must remove sticks, stones, and sometimes bullets!!
freshly harvested cacao beans plus some other junk
roasted cacao beanschocolate fountain!
Separation of Heterogeneous Mixtures…by magnetism
In this example, the magnetic property of the iron filings is used to separate it from the non-magnetic sulfur powder.
Physical Properties of Homogeneous Mixtures
• Pure substances have a unique set of physical properties that are different from any other pure substance
• The physical properties of mixtures are not unique...they differ with the relative amounts of the components in the mixture
Change in Boiling Point of a Solution vs. a Pure Liquid
Separating Liquid-Liquid Mixtures
Change in Boiling Point of a Solution vs. a Pure Liquid
Ch 2 – Atoms Molecules and IonsWhat did we know in the 1800’s? • Most natural materials are mixtures of
pure substances.• Pure substances are either elements or
combinations of elements called compounds.
• A given compound always contains the same proportions (by mass) of the elements...this is the law of definite composition
Law of Definite CompositionA given compound always has the same composition, regardless of where it comes from....or, a chemical compound always contains exactly the same proportion of elements by mass.
Water: 8 g oxygen (O) to 1 g hydrogen (H)
Carbon dioxide: 2.7 g oxygen (O) to 1 g carbon (C)
When two elements combine to form more than one compound, the different weights of one element that combine with the same weight of the other element are in a simple ratio of whole numbers.
What this means at the particulate level is that when elements combine, they do so in the ratio of small whole numbers.
For example: carbon and oxygen react to form CO or CO2, but not CO1.8.
Law of Multiple Proportions
Fig. 5-2, p. 121
Ok, there are atoms. What do they look like?
• It was known that atoms were neutrally-charged, but that they contained negatively-charged particles called electrons.
• Lord Kelvin (yes, that Lord Kelvin) proposed the “Plum-Pudding” Model (we will call it the “Chocolate-Chip Cookie” Model) of atomic structure.
• In this model, the atom is composed of discrete, negatively-charged electrons embedded in a cloud of uniform positive charge.
Uniform positive charge
Negatively-charged electrons
The Nuclear Atom1911 – Ernest Rutherford demonstrated the nuclear nature of the atom in which the empty space is 10,000 to 100,000 times larger than the size of the nucleus.
Atomic Structure1. Every atom contains small, dense nucleus.2. All of the positive charge and most of the mass
are concentrated in the nucleus.3. The nucleus is surrounded by a large volume
of nearly empty space that makes up the rest of the atom.
4. The rest of the atom is thinly populated by electrons, the total charge of which exactly balances the positive charge of the nucleus.
If an atom was the size of a baseball stadium, the nucleus would be the size of a fly on home plate.
What’s in an Atom?• Electron
– mass = 9.11 x 10-28 g 0.000549 amu (call this 0 amu)– charge = -4.8080 x 10-10 esu -1
• Proton– mass = 1.67 x 10-24 g 1.00728 amu (call this 1 amu)– charge = +4.8080 x 10-10 esu +1
• Neutron– mass = 1.68 x 10-24 g 1.00867 amu (call this 1 amu)– charge = 0 esu 0
(where esu = electrostatic unit; amu = atomic mass unit)
1 amu = 1.66 x 10-24 g
1 amu = 1/12 the mass of one carbon atom
What do the numbers of different particles mean?
• # Protons = chemical identity of the atom (which element is it?)– In an electrically-neutral atom, the number of protons in the nucleus is exactly
balanced by the number of electrons.
• # Electrons = ionic character of the atom. An ion has either more or fewer electrons than the electrically-neutral atom.
– anion = more electrons, so ion is negatively-charged– cation = fewer electrons, so ion is positively-charged
• # Neutrons = isotopic character of the atom – an atom of an element usually comes in at least 2 or 3 different isotopes
(sometimes more) – usually there will be one isotope that is far more abundant than the others
• If the number of protons is changed, the chemical identity of the atom is changed.
A few definitions. . .• Atomic number (Z): the number of protons in the nucleus of an atom• Mass number (A): the sum of the numbers of protons and neutrons in the
nucleus of an atom• Atomic Mass: the mass of one atom, expressed in amu• Atomic Weight: an average of the atomic masses of the most common
isotopes
O8
16.00
Atomic number (Z)
Atomic Weight (related to A)
In the periodic table...
O816
O16XZ A
or
Atomic symbol (X)
For example:Element symbol (X)
Atomic Symbol
Let’s count some particles
Co2760
Cl1737
U92238
Cobalt-60
Chlorine-37
Uranium-238
# protons # electrons # neutrons
27 27 60 – 27 = 33
17 17 37 – 17 = 20
92 92 238 – 92 = 146
QUESTIONOf the following three choices, which would have the greatest number of neutrons?
1. 137Ba2+
2. 128Te2–
3. 133Cs
A = 137 Z = 56 # neutrons = 137 – 56 = 81
A = 128 Z = 52 # neutrons = 128 – 52 = 76
A = 133 Z = 55 # neutrons = 133 – 55 = 78
QUESTIONOf the following, which would NOT qualify as an isotope of 35Cl?
1. 36Cl
2. 35Cl–
3. 37Cl–
Not an isotope because # neutrons is the same.
QUESTIONCalcium plays several critical roles in the functioning of human cells. However, this form of calcium is the ion made with 20 protons and 18 electrons. Therefore the ion would be…
1. positive and called an anion.
2. positive and called a cation.
3. negative and called an anion.
4. negative and called a cation.
1A
2A 3A 4A 5A 6A 7A
8A
• Alkali Metals ... soft, shiny metals; react vigorously with water; rarely found in elemental form
• Alkaline Earth Metals ... soft, shiny metals; react less vigorously with water than alkali metals; rarely found in elemental form
• Halogens ... gases: F, Cl; liquid: Br; solid: I; highly reactive; F is the most reactive element; all quite toxic; not found in elemental form
• Noble Gases ... all gases; largely unreactive, although Kr and Xe can form compounds; found in minute quantities in the atmosphere
Meet the Periodic Table
Hello!!
Period
Group
• Metals … good conductors of heat, electricity; malleable solids. Tend to lose electrons in reactions to form cations.
• Non-metals … poor conductors; not malleable. Tend to gain electrons in reactions to form anions.
• Metalloids … both metallic and nonmetallic properties
1A
2A 3A 4A 5A 6A 7A
8A
Metals
Non-metalsB
As
Sb Te
Po At
Ge
Si
QUESTIONFrom the following list select the element that is most likely to become an anion during a chemical reaction.
1. Hydrogen
2. Tungsten
3. Germanium
4. Bromine Nonmetals tend to gain electrons in reactions.
QUESTIONOf the following, which is most likely to become a cation as a result of a chemical reaction? What would be the charge on that cation?
1. N; –3
2. Ne; +1
3. Na: +1
4. Not enough information given to predict.
Metals tend to lose electrons in reactions.
Chemical Nomenclature Outline• Chemical formulas of elements• Naming binary compounds (two elements)
– compounds containing a metal and a nonmetal, aka ionic compounds
• Type I: metal forms one kind of cation (we have seen these before)• Type II: metal can form more than one kind of cation
– compounds containing two nonmetals• Naming compounds that contain polyatomic ions• Naming Acids and their anions
– acids that do not contain oxygen typically give monatomic ions (exceptions include CN-)
– acids that contain oxygen (“oxyacids”) always give polyatomic ions
Formulas of Elements
• The chemical formula of most elements is the atomic symbol, e.g. Li, Os, Xe, Pu
• Some elements form diatomic molecules. Memorize these: H2, N2, O2, F2, Cl2, Br2, I2
Horses Need Oats For Clear Brown I’s
• Other exceptions: P4, S8, C60
Metal can form only one kind of cation
Zn2+Ni2+ Ga3+
Ag+ Cd2+
Note: These cations are not isoelectronic with any noble gas!!
Binary Ionic Cmpds (Type I)
Cations (Mn+): name of atom + cation – Magnesium: Mg2+ ... magnesium cation– Cesium: Cs+ ... cesium cation
Anions (Xm-): root of atom name + -ide– Fluorine: F- ... fluoride anion– Sulfur: S2- ... sulfide anion– Selenium: Se2- ... selenide anion
Compound Name: <cation name> <anion name>Chemical Formula: MmXn
Binary Ionic Cmpds (Type I)
Example• Name the following compound: KCl
potassium chloride
• Name the following compound: CaBr2
calcium bromide
• Write the formula for: barium hydrideBaH2
• Write the formula for: aluminum sulfideAl2S3
Metal can form more than one kind of cation (see table 6.7)
These are a few common examples of metals that can form different
cations. This is not an exhaustive list.
Binary Ionic Cmpds (Type II)
Binary Ionic Cmpds (Type II) Cations (Mn+): name of atom + (oxidation state) + cation
– Oxidation state = charge. Use Roman numerals.– Iron:
• Fe2+ ... iron(II) cation• Fe3+ ... iron(III) cation
– Chromium:• Cr2+ ... chromium(II) cation• Cr3+ ... chromium(III) cation
Anions (Xm-): root of atom name + -ide (same as before)
Compound Name: <cation name> <anion name>Chemical Formula: MmXn
Example• Name the following compound: CuCl
copper(I) chloride
• Name the following compound: MnO2
manganese(IV) oxide
• Write the formula for: vanadium(V) fluorideVF5
• Write the formula for: tin(IV) bromideSnBr4
Binary Covalent Cmpds (Type III)
1. The first element in the formula is named first, and the full element name is used.
2. The second element is named as though it were an anion.
3. Prefixes are used to indicate the number of atoms present.
4. The prefix mono- is never used for naming the first element.• i.e., CO is carbon monoxide, not
monocarbon monoxide.
Prefix # Indicated
mono- 1
di- 2
tri- 3
tetra- 4
penta- 5
hexa- 6
hepta- 7
octa- 8
nona- 9
deca- 10
(two nonmetals, or a nonmetal and a metalloid)
Example• Name the following compound: BF3
boron trifluoride
• Name the following compound: I2O7
diiodine heptoxide
• Write the formula for: phosphorus trichloridePCl3
• Write the formula for: dinitrogen trioxideN2O3
Table 2.5 Common Polyatomic Ions
Ionic Compounds with Polyatomic Ions• Writing names and formulas is pretty much the same as
for binary compounds…– cation is named first, anion is named second– multiples of the ions are taken to ensure charge neutrality
• Example: – Na2SO4 … 2Na+ + SO4
2- sodium sulfate– manganese(II) hydroxide … Mn2+ + 2OH- Mn(OH)2
• The tricky part is learning where one ion ends and the next begins.
• Example: – KHSO4 … K+ + HSO4
- potassium hydrogen sulfate– NH4C2H3O2 … NH4
+ + C2H3O2
- ammonium acetate– NaH2PO3 ... Na+ + H2PO3
- sodium dihydrogen phosphite• Lucky for you guys, there are only a few common
polyatomic cations: NH4+ and Hg2
2+
Flowchart for Naming Compounds
No Yes
No
Polyatomic ion(s) present?
Naming procedure is similar to naming binary
ionic compounds.
Take organic chemistry