Patterns of Reactivity Five basic types of reactions. 1.
Combination two substances combine to make one new one. Generic: A
+ B C Ex) 2 Mg(s) + O2(g) 2 MgO(s)2 Mg(s) + O2(g) 2 MgO(s) 2.
Decomposition one substance decomposes to several new ones.
Generic: A B + C Ex) 2 NaN3(s) 2 Na(s) + 3 N2(g)2 NaN3(s) 2 Na(s) +
3 N2(g)
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Patterns of Reactivity 3. Single Replacement one element
replaces the other. Generic: A + BC AC + B Ex) 2 AgNO3(aq) + Cu(s)
Cu(NO3)2(aq) + 2 Ag(s)2 AgNO3(aq) + Cu(s) Cu(NO3)2(aq) + 2 Ag(s) 4.
Double Replacement (aka Metathesis) trading partners. Generic: AB +
CD AD + CD Ex) Hg(NO3)2(aq) + 2 NaI(aq) HgI2(s) + 2
NaNO3(aq)Hg(NO3)2(aq) + 2 NaI(aq) HgI2(s) + 2 NaNO3(aq) 5.
Combustion a rapid reaction with O2(g) producing a flame. Ex)
CH4(g) + 2 O2(g) CO2(g) + 2 H2O(l)
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Interpreting a Reaction A simple reaction like: N2(g) + 3 H2(g)
2 NH3(g), can be interpreted on many levels. Molecular Level: one
molecule of N2 plus three molecules of H2 react to form two
molecules of NH3
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Interpreting a Reaction For this reaction, we can establish
that: 1 molecule N2 = 3 molecules H2 1 molecule N2 = 2 molecules
NH3 3 molecules H2 = 2 molecules NH3 LEP #1
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Interpreting a Reaction The molecular level is really not
practical as we cannot do reaction on this scale. Rather, we can do
them on a mole scale. Thus: one mole of N2 plus three moles of H2
react to produce two moles of NH3. This means our relations can be
shortened to moles. LEP #1
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Limiting Reactant If given amounts of both reactants, we may
run out of one of them first. This reactant limits how much can be
made. Analogy: Putting together a bicycle parts on hand are 200
frames and 350 wheels. How many bicycles can you make? Ex) 2 H2 +
O2 2 H2O Suppose a vessel contained 10 molecules of H2 and 7
molecules of O2. How many water molecules are possible?
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Limiting Reactant This also applies to mole amounts as well.
LEP #2
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Stoichiometry Pronounced: stoy-key-OM-uh-tree. Relating
quantities in chemical reactions in particular masses. Cannot use
mole-to-mole ratios to convert mass of one substance to mass of
another by one single step. A mass-to-mass conversion must be done
in three steps.
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Stoichiometry
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Can be used to find a mass of another reactant or a product.
Can be part of a limiting reactant where amounts of both reactants
are given. Can also be asked to find a percent yield. Where the
Theoretical Mass is the maximum amount possible based on your
limiting reactant. LEP #3 and #4
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Solution A solution is a homogeneous mixture. Consists of a
solute and the solvent. Ex) NaCl added to water Chapter 12 will
show us a wide variety of solutions. Chapter 4 only water is the
solvent.
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Solution Concentration There are many methods for expressing a
solutions concentration and we will see more methods in Chapter 12.
Chemists typically use molarity (M). Molarity =
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Molarity Calculations can be from a mass and volume LEP #5. Or
from a molarity and volume LEP #6. Or involve a dilution LEP
#7.
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Solution Stoichiometry Reactions that take place in solution
can be analyzed using molarity and volume. Molarity can be used a
conversion factor. Can be calculation to find amount of other
reactant (volume or mass). Can be limiting reactant problem. LEP
#8, #9
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Dissolving an Ionic Compound When sodium chloride is added to
water, the ions are pulled apart. By itself, pure water is a poor
conductor of electricity. When an ionic compound dissolves, it
produces ions. These ions can carry a charge through the solution
and are referred to as electrolytes.
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Electrolytes vs. Non-electrolytes
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Electrolytes Strong Electrolyte completely dissociates to
produce 100% ions in solution. Ionic compounds must be soluble in
water Strong Acids (6) = Strong Bases =
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Electrolytes Weak Electrolytes partially ionize to produce a
few ions. Solution is weakly conducting. Weak acids formula starts
with H, but not on list of S.A. Ex) HC 2 H 3 O 2, HF, HCHO 2, etc.
Weak bases ammonia or amines. Ex) NH 3, CH 3 NH 2, CH 3 CH 2 NH
2
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Non-electrolytes Molecular compounds that dissolve in water,
but produce no ions. Sugar molecules, C n (H 2 O) n Ex) C 6 H 12 O
6, C 5 H 10 O 5 C 1 to C 4 Alcohols, Aldehydes, Ketones Ex) CH 3
OH, CH 3 C CH 3 || O LEP #10
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Solubility Rules Provides general solubility only gives black
or white details. No detail on extent of solubility. Ex) 34 g /
100mL for KCl Some soluble compounds have low limit. Ex) 0.17 g /
100mL for Ca(OH) 2 Some insoluble compounds may be slightly
soluble. Ex) 0.45 g / 100mL for PbCl 2 Insoluble compound = (s).
Soluble compound = (aq). LEP #11, #12
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Activity Series Ranks the metals from most reactive to least
reactive. A metal HIGHER on the activity series will replace
(react) any metal ion beneath it. Will Mg(s) react with Cu +2 (aq)?
Will Sn(s) react with Fe +2 (aq)?
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Writing a Reaction A molecular equation shows all compounds
written as if they were molecules even substances that are known to
exist as ions. An ionic equation shows all aqueous compounds as
ions in solution. All aqueous compounds are broken apart.
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Writing a Reaction AgNO 3 (aq) + NaCl(aq) A Net Ionic equation
removes all of the spectator ions. Spectator ions are ones that do
not change from reactants to products. These are the aqueous
ions.
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Single Replacement Writing a single replacement reaction from
scratch. A + BC A and B trade places as long as predicted by
Activity Series. Watch out for charges! Special treatment for H +
(acid) will generate H 2 (g)! LEP #13
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Double Replacement Writing a double replacement reaction
involving a precipitation from scratch. AB + CD Trade partners A
goes with D and C goes with B. Once again, charges MUST be observed
when re- combining and formulas are written with cation first.
Reaction only happens if one of the two products is Insoluble (s).
LEP #14 a, b
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Double Replacement These reactions can also produce a gas like
CO 2 or H 2 S. An acid plus a carbonate or bicarbonate An acid plus
any sulfide An acid and a base react to form water also called
neutralization. Acid plus a base form water plus a salt. LEP #14 c,
d, e
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Oxidation Reduction Referred to as redox for short. This
process involves the loss and gain of electrons. Corrosion of
metals Batteries Oxidation = the loss of electrons. Reduction = the
gain of electrons. OIL RIG =
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Oxidation Numbers An accounting method used to assign each
element in a compound and oxidation state (number). Rules: 1. The
oxidation state of any element in its standard state is zero. Ex)
Na(s), Cl 2 (g), P 4 (s), etc. 2. The oxidation state of a
monoatomic ion is equal to its charge. Ex) Cu +2 (aq) = +2, Cl -1
(aq) = -1 3. The sum of all oxidation states in a compound should
equal zero.
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Oxidation Numbers 4. The sum of all oxidation numbers in an ion
will equal the charge on the ion. 5. Group 1A metals = +1, 2A metal
= +2, Al = +3. 6. Halogens: F = -1; Cl, Br, and I are usually -1
unless when O is present. Ex) NaClO 7. O = -2, unless in a peroxide
like H 2 O 2. S = -2 unless when O is present. 8. H = +1. LEP
#15
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Redox Reactions Once all elements in a reaction have been
assigned oxidation numbers, inspect to see if two elements have
changed. Cannot have oxidation without reduction! Ex) 2 Cu(s) +
S(g) Cu 2 S(s) Ex) Zn(s) + 2 HCl(aq) ZnCl 2 (aq) + H 2 (g) LEP
#16
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Redox Reactions Just to make things a little more confusing The
element or compound that was reduced = oxidizing agent. The element
or compound oxidized = reducing agent. Always from the perspective
of the REACTANTS.
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Acid-Base Titration These involve the neutralization reaction.
Endpoint = when all of the unknown solution has reacted. Indicator
= substance that changes color when the endpoint has been
achieved.
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Acid-base Titration Delivery of the known solution is achieved
using a buret. Measures to nearest 0.05mL.
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Acid-base Titration Typically, the known solution is the base
like NaOH. LEP #17
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Redox Titration Assay analysis of an ore and many other
applications. Common oxidizing agent is KMnO 4 LEP #18