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Title: General Chemistry Exam 1 Notes - Everything you need!
Description: I used to be a chemistry instructor for students struggling in General Chemistry. If you are struggling and need a quick crash course or refresher for your first Gen Chem exam, this is THE PERFECT study guide/crash course packet for you. Here are 33 pages of extremely detailed notes covering everything you would expect to be on the first exam of your General Chemistry course. The notes are all in large font with all equations and examples completed AND typed out for your convenience. All examples are worked out STEP BY STEP, including EXPLANATIONS every step of the way. Topics include: 1. Introduction, Measurements, Sig Figs 2. Atomic Theory, Molecules, Ions, Formulas 3. Nomenclature, Chemical Equations, Oxidation-Reduction reactions 4. Moles, % Comp, Empirical/Molecular Formulas 5. Stoichiometry, Limiting Reagent, % Yield 6. Molarity, Dilution, Solution Stoichiometry 7. Thermochemistry 8. Calorimetry, Hess’s Law, ΔHf°
Description: I used to be a chemistry instructor for students struggling in General Chemistry. If you are struggling and need a quick crash course or refresher for your first Gen Chem exam, this is THE PERFECT study guide/crash course packet for you. Here are 33 pages of extremely detailed notes covering everything you would expect to be on the first exam of your General Chemistry course. The notes are all in large font with all equations and examples completed AND typed out for your convenience. All examples are worked out STEP BY STEP, including EXPLANATIONS every step of the way. Topics include: 1. Introduction, Measurements, Sig Figs 2. Atomic Theory, Molecules, Ions, Formulas 3. Nomenclature, Chemical Equations, Oxidation-Reduction reactions 4. Moles, % Comp, Empirical/Molecular Formulas 5. Stoichiometry, Limiting Reagent, % Yield 6. Molarity, Dilution, Solution Stoichiometry 7. Thermochemistry 8. Calorimetry, Hess’s Law, ΔHf°
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Notes by Aaron Hui
Chemistry Lecture 02
...
17
● Diatomic molecules:
○ Rule of 7’s
...
● Ion - charged species
○ Cation: + charge
■ Metals, lose e○ Anion: - charge
■ Nonmetals, gain e● Monatomic ion - only 1 atom (Ex: Na+, N3+
)
○ Octet rule - want 8 valence e- (be like nearest noble gas)
■ Valence e- = group # (main-group elements)
● Metals: charge = group #
● Nonmetals: charge = group # - 8
● Polyatomic ion - more than 1 atom (Ex: OH-, NO3-)
● How many protons and electrons are in 23
13Al3+
○ Protons: 13 protons
○ Electrons: 10 electrons
● How many protons and electrons are in 78
34Se2○ Protons: 34 protons
○ Electrons: 36 electrons
● What is the formula of the phosphorus ion (phosphide)? How many electrons
are present?
○ P3-, (15+3)= 18 electrons
● Ionic compounds - cation(s) + anion(s)
○ Sum of charges must equal zero
○ The ionic compound NaCl
○ Always crystalline structures
● Writing Formulas of Ionic Compounds
○ Order: cation (+) then anion (-)
■ Do not write charges
○ If equal + and - charges
■ Ex: Na+ and Cl- = NaCl
■ Ex: Al 3+ and N 3- = AlN
○ If unequal charges - use crisscross method
■ Magnitude of the charge on one ion becomes the subscript for the
other
...
It’s a
diatomic molecule
...
○ Can only change coefficients NOT subscripts
■ Changing subscripts change the compound
○ Reduce coefficients to the lowest whole number
...
○ Ex: Propane (C3H8) reacts with oxygen to form carbon dioxide and water
■ C3H8 + O2 -> CO2 + H2O
■ C3H8 + 5O2 -> 3CO2 + 4H2O
● Treat polyatomic ions as a “unit”
○ Al + FeSO4 -> Al2(SO4)3 + Fe
○ 2Al + 3FeSO4 -> Al2(SO4)3 + 3Fe
● When an element is in 3 or more compounds, change the coefficient where it is
alone - you can even use a fraction
○ 2NH3(g) + O2(g) -> 2NO(g) + 3H2O(g)
○ 2(2NH3(g) + (5/2)O2(g) -> 2NO(g) + 3H2O(g))
○ 4NH3(g) + 5O2(g) -> 4NO(g) + 6H2O(g)
● Synthesis Reactions
○ Form 1 product
○ Examples:
■ Two elements react to make a compound
● Al + S -> Al2 + S3
■ Metal Oxide plus water gives a metal hydroxide
● CaO + H2O (not balanced) -> Ca2+ + OH- -> Ca(OH)2
■ Non-metal oxide plus water gives an acid
● SO2 + H2O -> H+ + SO32- -> H2SO3
● Decomposition Reactions
○ 1 reactant (opposite of synthesis reactions)
○ Examples (not balanced):
■ Compound breaks down into elements:
● H2O + electrical energy = H2 + O2
■ MEMORIZE: Heating a metal carbonate gives carbon dioxide and
a metal oxide
● CuCO3 -> CO2 + CuO
■ MEMORIZE: Metal hydroxides break down into a metal oxide and
water
● AgOH -> H2O + Ag2O
● Single Replacement Reactions
○ One element replaces another
○ Examples (not balanced):
■ Na + H2O (think of water as HOH) -> H2 + NaOH
■ Cl2 + NaI -> I2 + NaCl
● Double Replacement Reactions
○ Ions switch partners
○ Examples:
■ HCl(aq) + Ca(OH)2(aq) -> H2O + CaCl2
● Combustion
○ Compound + O2 -> CO2 + H2O
● Oxidation Number (ON): The charge the atom would have if electrons were
completely transferred
○ Free elements: ON = 0
○ Monatomic ions: ON = charge
■ Group 1A = +2, 2A = +2, Aluminum = +3
● Li+ = +1; Fe3+ = +3; O2-
= -2
○ Oxygen: ON usually -2
○ Hydrogen: ON usually +1
■ Bonded to metals (ex: LiH, CaH2)
...
○ Oxidizing agent is reduced, causes the other to be oxidized
...
What is the oxidizing agent in the
reaction? What substance is being oxidized?
○ Zn + CuSO4 -> Cu + ZnSO4
0 +2 same 0 +2 same
● Cu went from +2 to 0, so CuSO4 is the oxidizing agent (Cu is being
reduced)
● Zn went from 0 to +2, so Zn is the reducing agent (Zn is being oxidized)
● Example: Copper wire reacts with silver nitrate to form silver metal and
copper(II) nitrate
...
Lecture 03
...
17
● Average Atomic Mass - avg
...
42% 6 Li (6
...
85% 7 Li (7
...
0742 (6
...
446 amu
●
...
016 amu) = 6
...
941amu
● For compounds: use sum of the atomic masses (in amu)
○ Molecular Mass - for a molecule (covalent compounds)
■ SO2
● S (32
...
07 amu
■ CH4O
● C (12
...
008) + O (16
...
04 amu
■ C8H10N4O2
● C (8)(12
...
008) + N (4)(14
...
00) =
194
...
022 x 1023
○ Avogadro's Number
● Molar Mass (Molecular Weight)
○ Mass of 1 mole of *whatever* in grams
○ For any element, molecule, formula unit:
■ atomic/molecular/formula mass (amu) = molar mass (g)
■ 1 molecule = 64
...
07 g
● Using Molar Mass as a Conversion Factor:
○ How many moles of Na are in 3
...
45g N a *
mol N a
22
...
150 mol N a
○ Calculate the mass of 1
...
■
1
...
02 g H 2 O
mol H 2 O
= 28
...
2 mol sample?
■
35
...
022*10 23 atoms N a
mol N a
= 2
...
5 mol sample of copper?
■
6
...
022*10 23 atoms Cu
mol Cu
= 3
...
37 moles of ozone? How many oxygen
atoms are present
...
37 mol O 3 *
6
...
25 * 10 23 molec
...
25 * 10 23 molec
...
O 3
= 2
...
37 mol O 3 *
3 mol O
mol O 3
*
6
...
48 * 10 24 atoms O
○ How many C6H12O6 molecules are present in a 0
...
225 mol C 6 H
12 O 6 *
6
...
35 * 10 23 molec C 6 H
Part Two of the problem
1
...
C 6 H 12 O 6
12 O 6
= 8
...
○ “GO FOR THE MOL”
● Summary:
○ One mole of 2 different substances contain same # particles but
different masses
○ Mass (g) →(molar mass)→ Moles →(avogadros #)→ Particles
● How many atoms are in 0
...
551 g K *
mol K
39
...
022*10 23 atoms K
mol K
= 8
...
3*1023 formula units of NaCl
○
1
...
units N aCl *
mol N aCl
6
...
45 g N aCl
mol N aCl
= 13 g N aCl
● How many H atoms are in 72
...
5 g C 3 H 8 O *
mol C 3 H 8 O
60
...
022*10 23 atoms H
mol H
= 5
...
4 g of urea (NH2)2CO?
○
32
...
06 g urea
*
4 mol H
mol urea
*
6
...
30 * 10 24 atoms H
● Percent Composition - percent by mass of each element
...
00 g of a compound made of mercury and oxygen decomposes in 4
...
37 g of oxygen
HgxOy→Hg(ℓ) + O2(g)
○ Calculate the percent composition of C2H6O
■ Total 46
...
01 g)
% C = 2 46
...
14%
g *
(1
...
07
100% = 13
...
00g
% O = 46
...
73%
g *
○ Molecule “Y” (MM = 166 g/mol) contains 68
...
How many
fluorine atoms are in each molecule “Y?”
atoms (mass F )
% F = #mass
100%
compound *
...
00 g)
166 g
x = 6 atoms
● Types of formulas:
○ Chemical Formula (?)↔(?) Mass percent composition
○ Empirical Formula:
■ Smallest whole number ratio of elements
● H2O
● CH2O
● O
● NH2
○ Molecular Formula:
■ Exact number of atoms in a substance (true formula)
● H2O
● C2H12O6
● O3
● N2H4
Molecular Formula
Empirical
H2O
H2O
C2H12O6
CH2O
O3
O
N2H4
NH2
● Calculating the Empirical Formula from Percent Composition
○ Determine the empirical formula of ascorbic acid (vitamin C) which
contains 40
...
58% H, and 54
...
■ Start with grams of each element
● If % - assume 100 g
■ g → moles (molar mass)
40
...
58 g H *
mol C
12
...
008 g H
54
...
407 mol C
= 4
...
00 g O
= 3
...
406
3
...
540 O 3
...
33O * 3 = C3H4O3
3
...
406
○ Within +-
...
15 < x< x+
...
5 g ethanol
○ Collect 22
...
5 g H2O
CxHyOz + O2 → CO2 + H2O
11
...
0 g 13
...
To find moles of C and H:
22
...
01 g CO2
*
mol C
mol CO2
= 0
...
5 g H 2 O *
mol H 2 O
18
...
50 mol H
To find moles of Oxygen:
0
...
50 mol H *
12
...
008 g H
mol H
= 6
...
51 g H
11
...
00g − 1
...
0 g O
4
...
00 g O
= 0
...
500
H 1
...
25
= C2H6O
0
...
25
0
...
07
...
407 g of the hydrate was
heated to drive off the water of hydration
...
332g Ba and 6
...
■ BaxIy ZH2O → BaxIy + ZH2O↑
Hydrate
anhydrous
10
...
332 g Ba
6
...
332 g Ba *
6
...
3 g Ba
mol I
126
...
02426 mol Ba
= 0
...
407 g − 3
...
188 g = 0
...
887 g H 2 O *
Ba
B aI
...
02426
2
I
...
02426
mol H 2 O
18
...
0493 mol H 2 O
...
0426 2
2H 2 O
● Determining Molecular Formulas
○ Need empirical formula + ~molar mass
○ (empirical formula)n = molecular formula
○ n must be an integer
■
n=
molar mass
empirical molar mass
● Stoichiometry - Mass Changes in Rxns
○
Conversion factor (mole ratio) is derived from coefficients in balanced chemical
equation
...
Write balanced equation
2
...
Find mol of desired substance
4
...
04 g CH 3 OH
*
4 mol H 2 O
2 mol CH 3 OH
*
18
...
■ Guys are limiting reagent
...
● Finding the Limiting Reagent
1
...
Assume each reagent is completely used up & calculate how much
product is formed
...
Limiting reagent yields the smallest amount of product
...
0 g of Al and 75
...
Which reagent is limiting and how many grams of H2 are produced?
How many grams of each reagent remains? If 1
...
■ 2Al + 6HCl → 2AlCl3 + 3H2
50
...
0g
50
...
98 g Al
75
...
46 g HCl
*
*
2
...
60 g H 2
2
...
07 g H 2
2
...
Start with L
...
(0 g HCl left since its L
...
)
75
...
46 g HCl
*
2 mol Al
6 mol HCl
*
26
...
5 g Al used up
Al : 50
...
5 g = 31
...
92 g
2
...
6%
OTHER METHOD FOR DETERMINING L
...
1
...
Compare to what was given
50
...
98 g Al
*
6 mol HCl
2 mol Al
*
36
...
Don’t have 203 g, only have 75 g, thus HCl is
L
...
QUIZ 1 TOPICS:
Sig fig
Measurements
Dim Analy
Atomic Theory
Writing formulas
Nomenclature
Writing chem equations
Redox reactions
Exp 2:
Mix: CuCO3 and CuO
CuCO3 and CuO →(heat) ____ (g) + ____
CuO does not react
——
H2 + O2 →
H2O
1 mol O2 *
2 mol O
mol O2
*
mol H 2 O
mol O
mol O
= 2 mol H 2 O → 2 mol H 2 O
2
● Arrhenius acid - produces H+ (H3O+) in water
○ HCl, HNO3, H2SO4, H3PO4
○ Hydronium ion, hydrated proton, H3O+
● Arrhenius base - produces OH- in water
○ NaOH, KOH, Ba(OH)2
● Bronsted acid (incorporates ALL arrhenius acids and some additional ones) proton (H+) donor
○ H in front
● Bronsted base - proton acceptor
○ Needs a lone pair, often ● Monoprotic acids - each unit yield 1 H+
○ HCl → H+ + Cl● Diprotic acids - each unit yields 2 H+
○ H2SO4 → 2H+ + SO42● Triprotic acids - each unit yields 3 H+\
● Acid-Base Reactions
○ Neutralization reactions - H+ and OH- combine to form H2O
○ HCl (aq) [acid] + NaOH (aq) [base] → NaCl (aq) [salt] + H2O [water]
■ Salt - ionic compound without H+, OH-, or O2
○ Bronsted reactions
■ Transfer only ONE proton
● NH3 (aq) + HF (aq) ↔ NH4+ (aq) + F- (aq)
Base acid
conj
...
Base
Lecture 03
...
17
● Reactions of Acids
○ React with some metals to produce H2
○ React with carbonates (CO32-) and bicarbonates (HCO3-) to produce CO2
...
M = molarity =
mol solute
L solution
What is the molarity of a solution containing 232 g of Kl in 500
...
0 g KI
500
...
40 mol KI
0
...
40 mol KI
L
1000 mL
= 0
...
80 M KI
What is the molarity of an 50
...
36 g of ethanol?
1
...
0 mL soln *
0
...
0500 L
mol ethanol
46
...
295 mol
= 0
...
590 M ethanol
● Using molarity as a conversion factor
○
L solution ↔ mol of solute
What mass of Kl is required to make 250
...
53 M Kl solution?
250
...
53 mol KI
L soln
*
166
...
5 g KI
What volume of HCl solution is required to make a 3
...
2 g of HCl
34
...
46 g HCl
*
L soln
3
...
250 L
● Dilution - prepare a less concentrated solution from a more concentrated one
...
0 mL of 0
...
00 M
HNO3? Approximately how much water would you need to add?
M 1V 1 = M 2V 2
(4
...
200 M )(60
...
00 mL
Start with 3
...
00 M HNO3
Add H2O until final volume is 60
...
0 mL − 3
...
0 mL approx how much H 2 O we add
34
...
07 M NaOH is mixed with 165
...
What is the
final concentration of NaOH solution assuming the volumes are additive?
M 1V 1 = M 2V 2
(5
...
2 mL) = M 2 (165
...
2 mL)
M 2 = 0
...
What is the concentration of the NaOH solution if 158 mL of NaOH is required
titrate 25
...
50 M H2SO4 standard solution?
H 2 SO4 + 2N aOH → 2H 2 O + N a2 SO4
25
...
225 mol N aOH
0
...
225 mol N aOH
= 1
...
2 M H2SO4 solution are needed to neutralize 30
...
256 M KOH solution?
H 2 SO4 + 2KOH → 2H 2 O + K 2 SO4
30
...
256 mol KOH
L
*
mol H 2 SO4
2 mol KOH
*
L H 2 SO4
6
...
63 mL H 2 SO4
THERMOCHEMISTRY
● Thermochemistry - the study of heat changes in chemical reactions
● Energy - capacity to do work (force acts through a distance) or transfer heat
○
SI unit: Joules (J)
○
Calorie
○
1 cal = 4
...
○
Potential energy is the same
...
○
Base sign on system:
■ +q heat added
■ +w work done on system
● Pushing on a gas
■ -q heat removed
■ -w work done by the system
● Gas pushing out
■ Hot q<0
■ Cold q>0
Lecture 3
...
17
● Pressure-Volume (PV) Work:
○ Work done by an expanding gas (w is - )
○ Work done on a gas compressing it (w is + )
● Heat
○ Exothermic process - releases heat
■ 2H2 (g) + O2 (g) → 2H2O (l) + energy
■ H2O (g) → H2O (l) + heat
■ FEELS HOT
○ Endothermic process - absorbs heat
■ Energy + 2HgO (s) → 2Hg (l) + O2
■ Energy + H2O (s) → H2O (l)
■ FEELS COLD
○ Solid →(endo)→ Liquid →(endo)→ Gas
○ Solid ←(exo)← Liquid ←(exo)← Gas
● Enthalpy (H)
○ ΔH = heat given off or absorbed during a reaction at constant pressure
...
01 kJ/mol (endothermic)
H2O (s) + heat → H2O (l)
H2O (s) + 6
...
4 kJ/mol (exothermic)
(negative sign means put heat on the product side)
CH4 (g) + 2O2 (g) → CO2 (g) + 2H2O (l) + heat
CH4 (g) + 2O2 (g) → CO2 (g) + 2H2O (l) + 890
...
4 kJ/mol
890
...
01 kJ/mol
H2O (l) → H2O (s)
ΔH = -6
...
● Practice:
○ How much heat is evolved (released/produced) when 74
...
5 kJ/mol
74
...
99 g N a
*
367
...
47*103 kJ of heat is produced, how many grams of oxygen must have
reacted?
P4 (s) + 5O2 (g) → P4O10 (s)
ΔH = -3013 kJ/mol
(6
...
00 g O2
mol O2
= 344 g O2
● Calorimetry
○ Specific heat (s) - heat (q) required to raise the temperature of 1 g of the
substance by 1℃ (units: J/g*℃)
○ Heat capacity © - heat (q) required to raise the temperature of a given
quantity of the substance by 1℃ (units: J/℃)
C = m*s (m=mass)
Heat (q) absorbed or relased:
q = msΔt
Δt = tf - ti =
change in temp
q > 0 endo
q < 0 exo
J
○ MEMORIZE: 4
...
25℃ to 26
...
184 J/g * ℃
Δt = 26
...
25℃ = 22
...
184
)(22
...
80 * 10 3 J = 9
...
444 J/g * ℃
Δt = 5℃ - 94
...
444
)(89℃) = 34 kJ
g*℃
● Calculate the amount of energy (in kJ) released when 346 g of steam at 182℃
is converted to liquid water at 0℃
...
In ΔH of melting, it is called Heat of Fusion (q = nΔHfos, n = mol)
In ΔH of boiling, it is called Heat of Vaporization (q = nΔHvap, n = mol)
Swater = 4
...
99 J/g℃
ΔHvap = 40
...
01 kJ/mol
q = msg Δt
J
q = (346 g H 2 O)( 1
...
28 J = 56
...
02 g H2 O )( 40
...
5 kJ + 783 kJ + 145 kJ = 985 kJ
EXPERIMENT 3
● Partners
● Calorimeters - checkout 1/partner
● Part 1
○ Heat of neutralization of HCl(aq) and NaOH(aq)
■ Bottles from the sink (not on shelves)
○ 2 trials for each part
○ Stir until mixed and let it sit
● Part 2
○ Heat of solution (ΔH) of NaOH(s)
■ ΔH =
kJ
mol
○ Keep all the containers closed
○ Clean up immediately
○ Top loading balances
○ 10-15 pellets of NaOH = 2 g
○ Only get one sample of NaOH at a time
○ Need 3 data points after temp goes down
○ Keep stirring until pellets dissolve
● Part 3
○ Heat of reaction of HCl(aq) and NaOH(s)
...
Lecture 3
...
17
● Calorimeter
○ No heat enters or leaves
○ Assume no heat is absorbed by calorimeter
○ qsys = qA + qb = 0
■ qA =
-qB
○ A 13
...
36℃ is placed in a calorimeter containing
100
...
35℃
...
57℃
...
25 g) s (22
...
36℃) = (100
...
184
)(22
...
35℃)
g℃
s = 2
...
14 g stainless steel ball (s = 0
...
82℃ is placed in a
calorimeter containing 120
...
44℃
...
-qmetal =
qh2o
-msΔT metal = msΔT h2o
J
− (30
...
470J
)(tf − 117
...
0 g)( 4
...
44℃)
g℃
g℃
− 14
...
2189 = 502
...
3552
10941
...
366 T f
T f = 21
...
○ 1
...
49 kg of water
from 20
...
54℃
...
ΔHrxn
2CH 3 OH + 3O2 → 2CO2 + 4H 2 O
ΔH(kJ/mol) =
q
mol
or ΔH(kJ/g) =
q
mass
q = msΔT
g 4
...
49 kg)( 1000
)( g℃ )(24
...
34℃)( 1000
)
kg
J
q = 43
...
92 g CH 3 OH *
mol CH 3 OH
32
...
0599 mol CH 3 OH
-qcombustion = qH2O
ΔH =
43
...
0599 mol
= −
730
...
kJ
mol CH 3 OH
● Problems - transferring heat
○ NaOH (s) is added to water in a calorimeter forming a solution with a
specific heat of 0
...
mL, and a density of 1
...
The temperature rises 4
...
7 kcal/mol (ΔH)
...
98 cal
kcal
q = (110
...
03
)( g℃ )(4
...
477 kcal
0
...
7 kcal
*
40
...
0 g N aOH
● Hess’s Law
○ Standard enthalpy of formation ΔH°f
■ ° means standard state:
● gas: 1 atm
● solid and liquid: 1 mol,
● Aq: 1 M,
● All 25℃
■
means formation of 1 mol from its elements
f
■ For element in most stable form: ΔH°f =
0
● Examples: ΔH°f (O2(g)) = 0 ; ΔH°f (C,
(s), graphite) = 0
Cu(s) + S(s) + O2(g) → CuSO4(aq) ΔH°f (CuSO4(aq))
C(s, graphite) + 12 O2 → CO(g) ΔH°f (CO(g)) = -110
...
19 kJ/mol
● Standard enthalpy of reaction (ΔH°rxn) - at 1 atm
○ Hess’s Law: enthalpy change is the same whether the reaction takes
place in one step or a series of steps
ΔH°rxn = ΣnΔH°f (products) − ΣmΔH°f (reactants)
aA + bB → cC + dD
ΔH°rxn = [cΔH°f (C) + dΔH°f (D)] − [aΔH°f (A) + bΔH°f (B)]
Liquid benzene C6H6 burns in air to produce carbon dioxide and liquid water
...
How much heat (in kJ) is released per gram
of benzene consumed?
Assume standard states
2C 6 H 6 (l) + 15O2 → 12CO2 (g) + 6H 2 O(l) ΔH°rxn
ΔH°rxn = 12ΔH°f (CO2 (g)) + 6ΔH°f (H 2 O(l)) − 2ΔH°f (C 6 H 6 (l)) − 15ΔH°f (O2 (g))
kJ
kJ
0 kJ
ΔH°rxn = 12( −393
...
9
) − 2( mol49CkJH ) − 15( mol
) = − 6535
...
4 kJ
2 mol C 6 H 6
*
mol C 6 H 6
78
...
836 kJ/g C 6 H 6
● 50
...
Liquid water is formed/
Calculate the enthalpy of reaction
...
7 kJ
0 kJ
ΔH°rxn = 4( −393
...
9
) − 2( mol
) − 7( mol
) = − 3120
...
0 g C 2 H 6 *
mol C 2 H 6
30
...
0 kJ
2 mol C 2 H 6
2
6
2
= 2
...
5 kJ/mol
S (rhomic) + O2 (g) → S O2 (g)
ΔH°rxn = − 296
...
6 kJ/mol
ΔH° (kJ/mol)
+
C (s, graphite) + O2 → C O2 (g)
-393
...
4)
2SO2 (g) + C O2 (g) → C S 2 (l) + 3O2 (g)
1073
...
5 + 2(− 296
...
6) kJ/mol = 87
...
4 kJ/mol
C (s, graphite) + O2 (g) → C O2 (g)
ΔH°rxn = − 393
...
9 kJ/mol
ΔH° (kJ/mol)
2C(s, graphite) + 2O2 (g) → 2CO2 (g)
2(-393
...
4)
4H 2 (g) + 2O2 (g) → 4H 2 O(l)
4(-285
...
8 kJ/mol
But we need it to be per 1 mol CH3OH(l) so divide by 2
−477
...
9 kJ/mol
● Thermal Effects of Physical Processes
○ Hydration - ions are surrounded by water
○ Lattice energy (U) - energy required to completely separate 1 mol of an
ionic compound into gaseous ions
○ Heat of hydration ΔH°hydr - energy associated with the hydration process
○ Heat of dilution - heat change associated with the dilution process
Title: General Chemistry Exam 1 Notes - Everything you need!
Description: I used to be a chemistry instructor for students struggling in General Chemistry. If you are struggling and need a quick crash course or refresher for your first Gen Chem exam, this is THE PERFECT study guide/crash course packet for you. Here are 33 pages of extremely detailed notes covering everything you would expect to be on the first exam of your General Chemistry course. The notes are all in large font with all equations and examples completed AND typed out for your convenience. All examples are worked out STEP BY STEP, including EXPLANATIONS every step of the way. Topics include: 1. Introduction, Measurements, Sig Figs 2. Atomic Theory, Molecules, Ions, Formulas 3. Nomenclature, Chemical Equations, Oxidation-Reduction reactions 4. Moles, % Comp, Empirical/Molecular Formulas 5. Stoichiometry, Limiting Reagent, % Yield 6. Molarity, Dilution, Solution Stoichiometry 7. Thermochemistry 8. Calorimetry, Hess’s Law, ΔHf°
Description: I used to be a chemistry instructor for students struggling in General Chemistry. If you are struggling and need a quick crash course or refresher for your first Gen Chem exam, this is THE PERFECT study guide/crash course packet for you. Here are 33 pages of extremely detailed notes covering everything you would expect to be on the first exam of your General Chemistry course. The notes are all in large font with all equations and examples completed AND typed out for your convenience. All examples are worked out STEP BY STEP, including EXPLANATIONS every step of the way. Topics include: 1. Introduction, Measurements, Sig Figs 2. Atomic Theory, Molecules, Ions, Formulas 3. Nomenclature, Chemical Equations, Oxidation-Reduction reactions 4. Moles, % Comp, Empirical/Molecular Formulas 5. Stoichiometry, Limiting Reagent, % Yield 6. Molarity, Dilution, Solution Stoichiometry 7. Thermochemistry 8. Calorimetry, Hess’s Law, ΔHf°