MCAT Review Sheets PDF

Summary

This document provides review sheets for various sections of the MCAT, including general chemistry, organic chemistry, biology, biochemistry, behavioral sciences, physics and math. It was revised in 2019 and is a helpful resource for MCAT preparation.

Full Transcript

MCAT REVIEW SHEETS
Revised 2019

Please send questions or comments to:
[email protected]
 Contents

General Chemistry Biology
1 Atomic Structure 1 1 The Cell 25
2 The Periodic Table 2 2 Reproduction 26
3 Bonding and Chemical Interactions 3 3 Embryogenesis and Development 27
4 Compounds and Stoichiometry 4 4 Nervous System 28
5 Chemical Kinetics 5 5 Endocrine System 29
6 Equilibrium 6 6 Respiratory System 30
7 Thermochemistry 7 7 Cardiovascular System 31
8 The Gas Phase 8 8 Immune system 32
9 Solutions 9 9 Digestive System 33
10 Acids and Bases 10 10 Kidney and Skin 34
11 Oxidation-Reduction Reactions 11 11 Muscular System 35
12 Electrochemistry 12 12 Genetics and Evolution 36

Organic Chemistry Biochemistry
1 Nomenclature 13 1 Amino Acids, Peptides, and Proteins 37
2 Isomers 14 2 Enzymes 38
3 Bonding 15 3 Nonenzymatic Protein Function & Protein Analysis 39

4 Analyzing Organic Reactions 16 4 Carbohydrate Structure and Function 40
5 Alcohols 17 5 Lipid Structure and Function 41
6 Aldehydes and Ketones I 18 6 DNA and Biotechnology 42
7 Aldehydes and Ketones II 19 7 RNA and the Genetic Code 43
8 Carboxylic Acids 20 8 Biological Membranes 44
9 Carboxylic Acid Derivatives 21 9 Carbohydrate Metabolism I 45
10 N- and P-Containing Compounds 22 10 Carbohydrate Metabolism II 46
11 Spectroscopy 23 11 Lipid and Amino Acid Metabolism 47
12 Separations and Purifications 24 12 Bioenergetics and Regulation of Metabolism 48

i
Behavioral Sciences Appendix
1 Biology and Behavior 49 A Organic Chemistry Common Names 73
2 Sensation and Perception 50 B The Heart and Oxygen Transport 74
3 Learning and Memory 51 C Brain 75
4 Cognition, Consciousness, and Language 52 D Endocrine Organs and Hormones 76
5 Motivation, Emotion, and Stress 53 E Lab Techniques 77
6 Identity and Personality 54 F DNA and RNA 78
7 Psychological Disorders 55 G DNA Replication 79
8 Social Processes, Attitudes, and Behavior 56 H The Central Dogma 80
9 Social Interaction 57 I Amino Acids 81
10 Social Thinking 58 J Enzyme Inhibition 82
11 Social Structure and Demographics 59 K Metabolism Overview 83
12 Social Stratification 60 L Glycolysis 84
M Gluconeogenesis 85
N Citric Acid Cycle 86
Physics and Math O Oxidative Phosphorylation 87
1 Kinematics and Dynamics 61 P More Metabolic Pathways 88
2 Work and Energy 62 Q Essential Equations 89
3 Thermodynamics 63
4 Fluids 64
5 Electrostatics and Magnetism 65
6 Circuits 66
7 Waves and Sound 67
8 Light and Optics 68
9 Atomic and Nuclear Phenomena 69
10 Mathematics 70
11 Design and Execution of Research 71
12 Data-Based and Statistical Reasoning 72

ii
General Chemistry 1: Atomic Structure

A
Z X A = Mass number = protons + neutrons
Z = Atomic number = # of protons
Note: Atomic Weight = weighted average

Scientist Contributions
Rutherford Model: 1911. Electrons surround a nucleus.
Bohr Model: 1913. Described orbits in more detail.
Farther orbits = ­Energy AHED Mnemonic
Absorb light
Photon emitted when n¯, absorbed when n­
Higher potential
Heisenberg Uncertainty: It is impossible to know the momentum and Excited
position simultaneously. Distant from nucleus
Hund’s Rule: e- only double up in orbitals if all orbitals first
have 1 e-.
Pauli Exclusion Principle: Paired e- must be + " , − ". Diamagnetic vs. Paramagnetic
# #
Diamagnetic: All electrons are paired
­¯ REPELLED by an external magnetic field
Constants Light Energy Paramagnetic: 1 or more unpaired electrons
() ­ PULLED into an external magnetic field
Avogadro’s Number: 6.022 × 10#F = 1 mol 𝐸=
l
𝐸 =h𝑓
Follow Hund’s rule to build the atom’s electron configuration. If 1 or more
Planck’s (h): 6.626 × 10 HFI
J s 𝑓 = frequency orbitals have just a single electron, the atom is paramagnetic. If there are
h = Planck 8 s constant no unpaired electrons, then the atom is diamagnetic.
Speed of Light (c) 3.0 × 10K m
c = speed of light
s Examples:
He = 1s2 = diamagnetic and will repel magnetic fields.
C = 1s22s22p2 = paramagnetic and will be attracted to magnetic fields.

Quantum Numbers
Quantum Possible
Name What it Labels Notes
Number Values
Atomic Orbitals on the Periodic Table
n Principal e- energy level or
shell number
1, 2, 3, … Except for d- and f-orbitals,
the shell # matches the row of
the periodic table.

l Azimuthal 3D shape of orbital 0, 1, 2, …, n-1 0 = s orbital
1 = p orbital
2 = d orbital
3 = f orbital
4 = g orbital

ml Magnetic Orbital sub-type Integers
–l ® +l
" "
ms Spin Electron spin
+# , −#

Maximum e- in terms of n = 2n2
Maximum e- in subshell = 4l + 2

Free Radical: An atom or molecule with an unpaired electron.

The Aufbau Principle

3D shapes of s, p, d, and f orbitals

1
 General Chemistry 2: The Periodic Table

Alkali Metals
ds
lloi Noble Gases
Alkaline Earth Metals a
et Halogens
M
Non-metals

Post Transition Metals

Transition Metals

Rare Earth Metal Rows

8A
Noble Gases have
no affinity for e-. It

Zeff IE EA
Unchanged

would take energy
to force an e- on
0 them

Pull between nucleus & valence e- Lose e- Gain e-
1st Ionization energies DHrxn < 0 when gaining e-
but EA is reported as positive value

Of the Noble Gases, only
Kr and Xe have an EN
Atomic
EN Kr
Xe
Common Electronegativities
Size
H C N O F
Force the atom exerts Exact 2.20 2.55 3.04 3.44 3.98 Only trend this direction
on an e- in a bond » 2.0 2.5 3.0 3.5 4.0 Cations < Neutral < Anions

2
General Chemistry 3: Bonding and Chemical Interactions
Bond Type According to DEN
0 Nonpolar
0.5 Polar
1.7 Ionic
Covalent Bonds covalent covalent

Covalent Bond: Formed via the sharing of electrons between
two elements of similar EN. Ionic Bonds
Bond Order: Refers to whether a covalent bond is a single, Ionic Bond: Formed via the transfer of one or more electrons
double, or triple bond. As bond order increases from an element with a relatively low IE to an
bond strength­, bond energy­, bond length¯. element with a relatively high electron affinity
Nonpolar Bonds: DEN < 0.5. DEN > 1.7.

Polar Bonds: DEN is between 0.5 and 1.7. Cation: POSITIVE +
Anion: NEGATIVE −
Coordinate A single atom provides both bonding electrons.
Covalent Bonds: Most often found in Lewis acid-base chemistry. Crystalline Lattices: Large, organized arrays of ions.

Intermolecular Forces Sigma and Pi Bonds Formal Charge
Hydrogen O-H, N-H, F-H Formal Charge = valence e0 − dots − sticks
1s
Strength

Dipole-Dipole Dots: Nonbonding e-
1s 1p Sticks: Pair of bonding electrons
London Dispersion
1s 2p
Note: Van de Waals Forces is a general term that includes
Dipole-Dipole forces and London Dispersion forces.

H-Bond acceptor
Valence Shell Electron Pair Repulsion Theory (VSEPR)
H-Bond donor
Electronic Geometry: Bonded and lone pairs treated the same.
Molecular Shape: Lone pairs take up less space than a bond to another atom.

Hybridization
e- Groups
Around
Bonded Lone Electronic Molecular Bond
Central Atom Pairs Pairs Geometry Shape Angle

sp
2 2
1
0
1
Linear
Linear
Linear
180°

3 0 Trig Planar
sp 2
3 2
1
1
2
Trigonal Planar Bent
Linear
120°

4 0 Tetrahedral
sp3
4 3
2
1
1
2
3
Tetrahedral
Trig Pyramidal
Bent
Linear
109.5°

5 0 Trigonal Bipyramidal

5 4 1 Trigonal Seesaw 90°
sp3d &
3 2 Bipyramidal T-Shaped 120°
2 3 Linear
6 0 Octahedral
sp3d2
6 5
4
1
2
Octahedral Square Pyramidal
Square Planar
90°

3
 General Chemistry 4: Compounds and Stoichiometry

Equivalents & Normality Naming Ions
Equivalent Mass of an acid that yields 1 mole of or H+
Mass: mass of a base that reacts with 1 mole of H+. For elements (usually metals) that can Fe2+ Iron(II)
form more than one positive ion, the Fe3+ Iron(III)
!"#$% !$'' charge is indicated by a Roman numeral in
GEW = Cu+ Copper(I)
!"# () "% *+ parentheses following the name of the
element Cu2+ Copper(II)

Equivalents = !$'' ", -"!."/01
234 Older method: –ous and –ic to the atoms Fe2+ Ferrous
with lesser and greater charge, Fe3+ Ferric
Normality = 35 For acids, the # of equivalents respectively
6 (n) is the # of H+ available
Cu+ Cuprous
from a formula unit. Cu2+ Cupric
Molarity = 0"%!$#789
!"# () "% *+ Monatomic anions drop the ending of the H- Hydride
name and add –ide F- Fluoride
O2- Oxide
S2- Sulfide
N3- Nitride
P3- Phosphide
Compound Formulas
Oxyanions = polyatomic anions that NO3- Nitrate
Empirical: Simplest whole-number ratio of atoms. contain oxygen. NO2 - Nitrite
MORE Oxygen = –ate
SO42- Sulfate
Molecular: Multiple of empirical formula to show LESS Oxygen = –ite
exact # of atoms of each element. SO32- Sulfite

In extended series of oxyanions, prefixes ClO- Hypochlorite
are also used. ClO2- Chlorite
MORE Oxygen = Hyper- (per-) ClO3- Chlorate
LESS Oxygen = Hypo-
ClO4- Perchlorate

Polyatomic anions that gain H+ to for HCO3- Hydrogen carbonate or bicarbonate
anions of lower charge add the word HSO4 - Hydrogen sulfate or bisulfate
Hydrogen or dihydrogen to the front.
H2PO4- Dihydrogen phosphate

Types of Reactions
Combination: Two or more reactants forming one product
2H2 (g) + O2 (g) ® 2H2O (g)
Acid Names
Decomposition: Single reactant breaks down
2HgO (s) ® 2Hg (l) + O2 (g) -ic: Have one MORE oxygen than -ous.

Combustion: Involves a fuel, usually a hydrocarbon, and O2 (g) -ous: Has one FEWER oxygen than -ic.
Commonly forms CO2 and H2O
CH4 (g) + 2O2 (g) ® CO2 (g) + H2O (g)

Single-Displacement: An atom/ion in a compound is replaced by
another atom/ion
Cu (s) + AgNO3 (aq) ® Ag (s) + CuNO3 (aq)

Double-Displacement: Elements from two compounds swap places
(metathesis) CaCl2 (aq) + 2AgNO3 (aq) ® Ca(NO3)2 (aq) + 2AgCl (s)

Neutralization: A type of double-replacement reaction
Acid + base ® salt + H2O
HCl (aq) + NaOH (aq) ® NaCl (aq) + H2O (l)

4
General Chemistry 5: Chemical Kinetics
Units of Rate
m Order Rate Law Integrated Rate Law Half Life
Constant

0 zeroth order 𝑅=𝑘 [A] = [A]@ − 𝑘 𝑡 [A]@ 𝑀
𝑡^ =
_ 2𝑘 𝑠

1 first order 𝑅 = 𝑘 [A] [A] = [A]@ × 𝑒 &A 0 ln (2) 1
𝑡^ =
_ 𝑘 𝑠

2 second order 𝑅 = 𝑘 [A]_ 1 1 1 1
= + 𝑘𝑡 𝑡^ =
[A] [A]@ _ 𝑘 [A]@ 𝑀𝑠

[A] ln [A] 1
[A]

Zeroth Order Reaction First Order Reaction Second Order Reaction
Reaction Order and Michaelis-Menten Curve: At low
substrate concentrations, the reaction is approximately
FIRST-ORDER. At very high substrate concentration,
the reaction approximates ZERO-ORDER since the
Types of Reactions reaction ceases to depend on substrate concentration.
Combination: Two or more reactants forming one product.
2H2 (g) + O2 (g) ® 2H2O (g)
Equations
Decomposition: Single reactant breaks down.
2HgO (s) ® 2Hg (l) + O2 (g) Arrhenius: 𝑘 = 𝐴 × 𝑒 &'
)*
(

Combustion: Involves a fuel, usually a hydrocarbon, and O2 (g). Definition of Rate: For aA + bB ® cC + dD
Commonly forms CO2 and H2O.
D[-] D D D
CH4 (g) + 2O2 (g) ® CO2 (g) + H2O (g) Rate = −
/D0
=−
2D0
=
4D0
=
6D0

Single-Displacement: An atom or ion in a compound is replaced by Rate Law: rate = 𝑘 [A] = [B] ?
another atom or ion.
Radioactive Decay: [A]0 = [A]@ × 𝑒 A0
Cu (s) + AgNO3 (aq) ® Ag (s) + CuNO3 (aq)
Double-Displacement: Elements from two compounds swap places.
(metathesis) CaCl2 (aq) + 2AgNO3 (aq) ® Ca(NO3)2 (aq) + 2AgCl (s)
Neutralization: A type of double-replacement reaction.
Reaction Mechanisms
Acid + base ® salt + H2O Overall Reaction: A2 + 2B ® 2AB
HCl (aq) + NaOH (aq) ® NaCl (aq) + H2O (l)
Step 1: A2 + B ® A2B slow
Hydrolysis: Using water to break the bonds in a molecule. Step 2: A2B + B ® 2AB fast

A2B is an intermediate
Slow step is the rate determining step

Arrhenius Equation
Arrhenius: 𝑘 = 𝐴 × 𝑒 &'
)*
(

k = rate constant
A = frequency factor
Ea = activation energy
G
R = gas constant = 8.314
Gibbs Free Energy HIJ K
T = temp in K
∆G = EO − EO PQR
Trends: ­A Þ ­k
−∆G = Exergonic
­T Þ ­k (Exponent gets closer to 0. Exponent
becomes less negative)
+∆G = Endergonic

5
 General Chemistry 6: Equilibrium

Equilibrium Constant Kinetic (Ea) and Thermodynamic (DG) Control

aA + bB ⇌ cC + dD Kinetic Products: HIGHER in free energy than thermodynamic
products and can form at lower temperatures.
[C]( [D]+ “Fast” products because they can form more
Equilibrium Constant (Keq): 𝐾"# = quickly under such conditions.
[A]- [B]/

Thermodynamic Products: LOWER in free energy than kinetic products,
[C]( [D]+
Reaction Quotient (Qc): 𝑄1 = more stable. Slower but more spontaneous
[A]- [B]/ (more negative DG)

Exclude pure solids and liquids

Reaction Quotient Le Châtelier’s Principle

Q < Keq DG < 0, reaction ® If a stress is applied to a system, the system shifts to relieve that applied stress.

Q = Keq DG = 0, equilibrium Example: Bicarbonate Buffer
CO2 (g) + H2O (l) ⇌ H2CO3 (aq) ⇌ H+ (aq) + HCO3- (aq)
Q > Keq DG > 0, reaction ¬

¯pH Þ ­respiration to blow off CO2

­pH Þ ¯respiration, trapping CO2

6
General Chemistry 7: Thermochemistry
Systems and Processes Temperature (T) and Heat (q)
Isolated System: Exchange neither matter nor energy with Temperature (T): Scaled measure of average kinetic
the environment. energy of a substance.
Closed System: Can exchange energy but not matter with Celsius vs 0°C = 32°F Freezing Point H2O
the environment. Fahrenheit:
% 25°C = 75°F Room Temp
Open system: Can exchange BOTH energy and matter ℉ = ( ℃ ) + 32
&
37°C = 98.6°F Body Temp
with the environment.
Heat (q): The transfer of energy that results
Isothermal Process: Constant temperature.
from differences of temperature. Hot
Adiabatic Process: Exchange no heat with the environment. transfers to cold.
Isobaric Process: Constant pressure.
Isovolumetric: Constant volume. Enthalpy (H)
(isochoric)
Enthalpy (H): A measure of the potential energy of a system
found in intermolecular attractions and chemical
bonds.
States and State Functions Phase Changes: Solid ® Liquid ® Gas: ENDOTHERMIC since
gases have more heat energy than liquids and
State Functions: Describe the physical properties of an equilibrium liquids have more heat energy than solids.
state. Are pathway independent. Pressure, density,
temp, volume, enthalpy, internal energy, Gibbs free Gas ® Liquid ® Solid: EXOTHERMIC since these
energy, and entropy. reactions release heat.
Standard Conditions: 298 K, 1 atm, 1 M Hess’s Law: Enthalpy changes are additive.
Note that in gas law calculations, Standard
°
Temperature and Pressure (STP) is 0°C, 1 atm. D𝐻-./ from heat of formations
∆𝑯𝐫𝐱𝐧 = ∆𝑯°𝐩𝐫𝐨𝐝𝐮𝐜𝐭𝐬 − ∆𝑯°𝐫𝐞𝐚𝐜𝐭𝐚𝐧𝐭𝐬
°
Fusion: Solid ® liquid
°
Freezing: Liquid ® solid D𝐻-./ from bond dissociation energies
∆𝑯°𝐫𝐱𝐧 = ∆𝑯°𝐫𝐞𝐚𝐜𝐭𝐚𝐧𝐭𝐬 − ∆𝑯°𝐩𝐫𝐨𝐝𝐮𝐜𝐭𝐬
Vaporization: Liquid ® gas
Sublimation: Solid ® gas Entropy (S)
Deposition: Gas ® solid Entropy (S): A measure of the degree to which energy has
been spread throughout a system or between a
Triple Point: Point in phase diagram where all 3 phases exist.
system and its surroundings.
@
Supercritical Fluid: Density of gas = density of liquid, no distinction ∆𝑆 = ABC
D
between those two phases. Standard entropy of reaction
∆𝑺°𝐫𝐱𝐧 = ∆𝑺°𝐟,𝐩𝐫𝐨𝐝𝐮𝐜𝐭𝐬 − ∆𝑺°𝐟,𝐫𝐞𝐚𝐜𝐭𝐚𝐧𝐭𝐬

Note: Entropy is maximized at equilibrium.

Gibbs Free Energy (G)
Gibbs Free Energy (G): Derived from enthalpy and entropy.

D𝑮 = D𝐇 − 𝐓 D𝐒

Standard Gibbs free energy of reaction
D𝑮°𝐫𝐱𝐧 = ∆𝑮°𝐟,𝐩𝐫𝐨𝐝𝐮𝐜𝐭𝐬 − ∆𝑮°𝐟,𝐫𝐞𝐚𝐜𝐭𝐚𝐧𝐭𝐬
Gibbs Free Energy (G)
From equilibrium constant Keq
D𝑮 = D𝐇 − 𝐓 D𝐒 °
∆𝐺MNO = −R 𝑇 ln (𝐾VW )

DH DS Outcome From reaction quotient Q
°
+ + Spontaneous at HIGH temps ∆𝐺MNO = ∆𝐺MNO + R 𝑇 ln (𝑄)
Y
∆𝐺MNO = R 𝑇 ln (Z )
+ - Non-spontaneous at all temps B[

DG < 0 : Spontaneous
- + Spontaneous at all temps
DG = 0 : Equilibrium
- - Spontaneous at LOW temps
DG > 0 : Non-spontaneous
Note: Temperature dependent when DH and DS have same sign.

7
 General Chemistry 8: The Gas Phase

Ideal Gases Real Gases

Ideal Gas: Theoretical gas whose molecules occupy negligible space Real gases deviate from ideal behavior at ¯temperature & ­pressure
and whose collisions are perfectly elastic. Gases behave
At Moderately ­P, ¯V, Real gases will occupy less volume than
ideally under reasonably ­temperatures and ¯pressures.
or ¯T: predicted by the ideal gas law because the
STP: 273 K (0°C), 1 atm particles have intermolecular attractions.
1 mol Gas: At STP 1 mol of gas = 22.4 L At Extremely ­P, ¯V, Real gases will occupy more volume than
Units: 1 atm = 760 mmHg = 760 torr = 101.3 kPa = 14.7 psi or ¯T: predicted by the ideal gas law because the
particles occupy physical space.
Van der Waals 𝑛T 𝑎
d𝑃 + T j (𝑉 − 𝑛𝑏) = 𝑛R𝑇
Equation of State: 𝑉
a corrects for attractive forces
Ideal Gas Law b corrects for volume of the particles themselves

=
𝑷𝑽=𝒏𝐑𝑻 R = 8.314
>?@ A
B DE
Density of Gas: r =
C
= FG Kinetic Molecular Theory
DH CH DI CI
= (n is constant)
GH GI
Combined Gas Law: DH GI
Avg Kinetic 𝐾𝐸 = S 𝑚 𝑣 T = W
𝐾X 𝑇 𝐾X = 1.38 × 10[TW
=
V2 = V1( ) ( ) Energy of a Gas: T T A
DI GH
(𝐾𝐸 ∝ 𝑇)
L LH L
Avogadro’s Principle: = k or = CI (T and P are constant)
C CH I ­T = molecules move FASTER
­molar mass = molecules move SLOWER
Boyle’s Law: PV = k or P1V1 = P2V2 (n and T are constant)
Root-Mean-
C CH CI 3R𝑇
Charles’s Law: = k or =G (n and P are constant) Square Speed: 𝑢^>_ = `
G GH I 𝑀
D DH DI
Gay-Lussac’s Law: = k or =G (n and V are constant) Diffusion: The spreading out of particles from [high] ® [low]
G GH I

Effusion: The mvmt of gas from one compartment to another
through a small opening under pressure
Other Gas Laws Graham’s Law: bH E
= cEI
bI H

Dalton’s Law: PT = PA + PB + PC + … ¯molar mass = diffuse/effuse FASTER
(total pressure from ­molar mass = diffuse/effuse SLOWER
partial pressures)
Dalton’s Law: PA = XAPT (X = mol fraction)
(partial pressure from
total pressure)
[P]H [P]I
Henry’s Law: [A] = kH x PA or DH
= DI
= kH

Diatomic Gases
Exist as diatomic molecules, never a stand-alone atom.
Includes H2, N2, O2, F2, Cl2, Br2, and I2

Mnemonic: “Have No Fear Of Ice Cold Beer”

The 7 Diatomic Gases
8
General Chemistry 9: Solutions
Terminology Solubility Rules
Solution: Homogenous mixture. Solvent particles surround Soluble
solute particles via electrostatic interactions.
Na+, K+, NH4+
Solvation or The process of dissolving a solute in solvent. Most
Dissolution: dissolutions are endothermic, although dissolution of NO3-
gas into liquid is exothermic. Cl-, Br-, I- Except with Pb2+, Hg22+, Ag+
Solubility: Maximum amount of solute that can be dissolved in a
SO42- Except with Ca2+, Sr2+, Ba2+, Pb2+, Hg22+, Ag+
solvent at a given temp.
Molar Solubility: Molarity of the solute at saturation.

Complex Ions: Cation bonded to at least one ligand which is the e- Insoluble
pair donor. It is held together with coordinate covalent S2- Except with Na+, K+, NH4+, Mg2+, Ca2+, Sr2+, Ba2+
bonds. Formation of complex ions ­solubility.
O2- Except with Na+, K+, Sr2+, Ba2+
Solubility in Water: Polar molecules (with +/- charge) are attracted to
water molecules and are hydrophilic. Nonpolar OH- Except with Na+, K+, Ca2+, Sr2+, Ba2+
molecules are repelled by water and are hydrophobic. CrO42- Except with Na+, K+, Mg2+, NH4+

Polar = Hydrophilic PO43- & CO32- Except with Na+, K+, NH4+
Nonpolar = Hydrophobic

Concentration
-."" "01234
% by mass: × 100%
-."" "0123506
-014" "01234
Mole Fraction: 𝑋< =
303.1 -014"

Molarity: 𝑀 =
-014" "01234
1534>" 0? "0123506
Colligative Properties
-014" "01234
Molality: 𝐶- = AB 0? "01C463 Can also just be a lowercase m Colligative Properties: Physical properties of solutions that depend on
the concentration of dissolved particles but not
For acids, the # of equivalents on their chemical identity.
# 0? 4F25C.1463"
Normality: 𝑁 = (n) is the # of H+ available
1534>" 0? "0123506
from a formula unit. Raoult’s Law: Vapor pressure depression. 𝑃< = 𝑋< 𝑃

IP = Ksp saturated at equilibrium Osmotic Pressure: “Sucking” pressure generated by solutions in
IP > Ksp supersaturated, precipitate which water is drawn into solution.
Formation or Kf. The equilibrium constant for complex formation.
Stability Constant: Usually much greater that Ksp. p=𝑖𝑀R𝑇
𝑖 = vanb t Hoff factor
Common Ion ¯solubility of a compound in a solution that already 𝑀 = molar concentration of solute
Effect: contains one of the ions in the compound. The 𝑅 = gas constant
presence of that ion shifts the dissolution reaction to 𝑇 = temperature
the left, decreasing its dissociation.
Chelation: When a central cation is bonded to the same ligand
in multiple places. Chelation therapy sequesters
toxic metals.

9
 General Chemistry 10: Acids and Bases
Definitions Polyvalence & Normality
Arrhenius Acid: Produces H+ (same definition as Brønsted acid) Equivalent: 1 mole of the species of interest.
Arrhenius Base: Produces OH- Normality: Concentration of equivalents in solution.
Brønsted-Lowry Acid: Donates H+ (same definition as Arrhenius acid) Polyvalent: Can donate or accept multiple equivalents.
Brønsted-Lowry Base: Accepts H+ Example: 1 mol H3PO4 yields 3 mol H+. So, 2 M H3PO4 = 6 N.
Lewis Acid: Accepts e- pair
Lewis Base: Donates e- pair
Titrations
Note: All Arrhenius acids/bases are Brønsted-Lowry acids/bases, and
all Brønsted-Lowry acid/bases are Lewis acids/bases; however, the Half-Equivalence Point: The midpoint of the buffering region, in which half the
converse of these statements is not necessarily true. (midpoint) titrant has been protonated or deprotonated. [HA] =
[A& ] and pH = pK ) and a buffer is formed.
Amphoteric Species: Species that can behave as an acid or a
base. Amphiprotic = amphoteric species Equivalence Point: The point at which equivalent amounts of acid and base
that specifically can behave as a Brønsted- have reacted. 𝑁' 𝑉' = 𝑁P 𝑉P
Lowry acid/base. pH at Equivalence Point: Strong acid + strong base, pH = 7
Polyprotic Acid: An acid with multiple ionizable H atoms. Weak acid + strong base, pH > 7
Weak base + strong acid, pH < 7
Weak acid + weak base, pH > or < 7 depending on the
relative strength of the acid and base

Properties Indicators: Weak acids or bases that display different colors in the
protonated and deprotonated forms. The indicator’s
Water Dissociation Constant: 𝐾" = 10&'( at 298 K pKa should be close the pH of the equivalence point.
𝐾" = 𝐾) × 𝐾,
Tests: Litmus: Acid = red; Base = blue; Neutral = purple
pH and pOH: pH = −log [H4 ] [H4 ] = 10&67 Phenolphthalein: pH < 8.2 = colorless; pH > 8.2 = purple
pOH = −log [OH& ] Methyl Orange: pH < 3.1 = red; pH > 4.4 = yellow
pH + pOH = 14 Bromophenol Blue: pH < 6 = yellow; pH > 8 = blue
p scale value approximation: −log (𝐴 × 10&= ) Endpoint: When indicator reaches full color.
p value ≈ −(𝐵 + 0. 𝐴)
Polyvalent Acid/Base Multiple buffering regions and equivalence points.
Strong Acids/Bases: Dissociate completely Titrations:

Weak Acids/Bases: Do not completely dissociate
Acid Dissociation Constant: 𝐾 = [7FGH ][IJ] p𝐾) = −log (𝐾) ) Titration Setup
) [7I]

Base Dissociation Constant: 𝐾 = [KH][G7J] p𝐾, = −log (𝐾, )
, [KG7] Burette

p𝐾) + p𝐾, = p𝐾" = 14
Conjugate Acid/Base Pairs: Strong acids & bases / weak conjugate Titrant (strong acid in this example)
Weak acids & bases / weak conjugate
Neutralization Reactions: Form salts and (sometimes) H2O Analyte / Titrand
(weak base in this example) Conical flask

Buffers
Buffer: Weak acid + conjugate salt
Weak base + conjugate salt Titration Curve
When titrating a weak base with a strong acid
Buffering Capacity: The ability of a buffer to resist changes in pH. Maximum
buffering capacity is within 1 pH point of the pKa.
Midpoint
J
Henderson-Hasselbalch pH = pK + log [I ] pOH = pK ,
) [7I]
Equation:

[KH ] Equivalence Point
pOH = pK , + log [7G7]
𝑁' 𝑉' = 𝑁P 𝑉P

When [A-] = [HA] at the half equivalence point, log(1) = 0, so pH = pKa

10
General Chemistry 11: Oxidation-Reduction Reactions

Definitions Balancing via Half-Reaction Method

Oxidation: Loss of e- Separate the two half-reactions
Balance the atoms of each half-reaction. Start with all elements besides H
Reduction: Gain of e-
and O. In acidic solution, balance H and O using water and H+. In basic
With Respect to Oxidation is GAIN of oxygen solution, balance H and O using water and OH-
Oxygen Transfer: Reduction is LOSS of oxygen Balance the charges of each half-reaction by adding e- as necessary
Multiply the half-reactions as necessary to obtain the same number of e- in
Oxidizing Agent: Facilitates the oxidation of another
both half-reactions
compound. Is itself reduced
Add the half-reactions, canceling out terms on both sides
Reducing Agent: Facilitates the reduction of another Confirm that the mass and charge are balanced
compound. Is itself oxidized

Oxidation # Rules

Any free element or diatomic species = 0
Monatomic ion = the charge of the ion
When in compounds, group 1A metals = +1; group 2A metals = +2
When in compounds, group 7A elements = -1, unless combined with an element of greater EN
H = +1 unless it is paired with a less EN element, then = -1
O = -2 except in peroxides, when it = -1, or in compounds with more EN elements
The sum of all oxidation numbers in a compound must = overall charge

Net Ionic Equations

Complete Ionic Equation: Accounts for all of the ions present in a reaction. Split all
aqueous compounds into their relevant ions. Keep solid
salts intact.
Net Ionic Equation: Ignores spectator ions
Disproportionation Reactions: A type of REDOX reaction in which one element is both
(dismutation) oxidized and reduced, forming at least two molecules
containing the element with different oxidation states
REDOX Titrations: Similar in methodology to acid-base titrations, however,
these titrations follow transfer of charge
Potentiometric Titration: A form of REDOX titration in which a voltmeter measures
the electromotive force of a solution. No indicator is used,
and the equivalence point is determined by a sharp change
in voltage

11
 General Chemistry 12: Electrochemistry

Galvanic Cell Electrolytic Cell

Electrochemical Cells Emf & Thermodynamics

Anode: Always the site of oxidation. It attracts anions. Electromotive force and change in free energy always have
OPPOSITE signs.
Cathode: Always the site of reduction. It attracts cations.
Type of Cell 𝑬°𝐜𝐞𝐥𝐥 DG°
Red Cat = Reduction at the Cathode
Galvanic + -
e- Flow Anode ® Cathode
Electrolytic - +
Current Flow: Cathode ® Anode
° Concentration 0 0
Galvanic Cells: House spontaneous reactions. -DG, +Emf, +𝐸%#&&
(Voltaic) Anode = NEG, Cathode = POS
°
Electrolytic Cells: House non-spont reactions. +DG, -Emf, -𝐸%#&& ° ° °
𝐸%#&& = 𝐸"#$,%-./0$# − 𝐸"#$,-20$#
Anode = POS, Cathode = NEG °
∆𝐺° = −𝑛 F 𝐸%#&&
Concentration Specialized form of galvanic cell in which both electrodes are
Cells: made of the same material. It is the concentration gradient ∆𝐺° = −R 𝑇 ln (𝐾>? )
between the two solutions that causes mvmt of charge. ∆𝐺 = ∆𝐺° + R 𝑇 ln (𝑄)
Rechargeable Can experience charging (electrolytic) and discharging
Batteries: (galvanic) states.
Faraday constant (F): 96,485 C
Lead-Acid: Discharging: Pb anode, PbO2 cathode in a concentrated E
sulfuric acid solution. Low energy density. 1C=
F

Ni-Cd: Discharging: Cd anode, NiO(OH) cathode in a concentrated
KOH solution. Higher energy density than lead-acid batteries.
NiMH: More common than Ni-Cd because they have higher energy
density.
Nernst Equation
Describes the relationship between the concentration of
Cell Potentials species in a solution under nonstandard conditions and the
emf.
Reduction Potential: Quantifies the tendency for a species to gain e- °
When Keq > 1, then +𝐸%#&&
and be reduced. More positive Ered = greater
°
tendency to be reduced. When Keq < 1, then -𝐸%#&&
°
Standard Reduction Potential: 𝐸"#$ °. Calculated by comparison to the standard When Keq = 1, then 𝐸%#&& =0
hydrogen electrode (SHE). ° GH
𝐸%#&& = 𝐸%#&& − ln (𝑄)
° IJ
Standard Electromotive Force: 𝐸%#&&.
The difference in standard reduction
° K.KMNO
potential between the two half-cells. 𝐸%#&& = 𝐸%#&& − log (𝑄)
I
°
Galvanic Cells: +𝐸%#&&
°
Electrolytic Cells: -𝐸%#&&

12
Organic Chemistry 1: Nomenclature

IUPAC Naming Conventions
Step 1: Find the parent chain, the longest carbon chain that
contains the highest-priority functional group.
Step 2: Number the chain in such a way that the highest-priority
functional group receives the lowest possible number.
Step 3: Name the substituents with a prefix. Multiples of the same
type receive (di-, tri-, tetra-, etc.).
Step 4: Assign a number to each substituent depending on the
carbon to which it is bonded.
Step 5: Alphabetize substituents and separate numbers from each
other by commas and from words by hyphens.

Hydrocarbons and Alcohols Carboxylic Acids & Derivatives
Alkane: Hydrocarbon with no double or triple bonds.
Alkane = C) H(,)-,)
Naming: Alkanes are named according to the number of carbons
present followed by the suffix –ane. Carboxylic Acid
Alkene: Contains a double bond. Use suffix -ene.
Carboxylic Acid: The highest priority functional group because it
Alkyne: Contains a triple bond. Use suffix –yne. contains 3 bonds to oxygen.
Alcohol: Contains a –OH group. Use suffix –ol or prefix hydroxy-. Naming: Suffix –oic acid.
Alcohols have higher priority than double or triple bonds.
Diol: Contains 2 hydroxyl groups.
Geminal: If on same carbon
Vicinal: If on adjacent carbons

Ester Amide
Aldehydes and Ketones
Ester: Carboxylic Acid derivative where –OH is replaced
with -OR.
Amide: Replace the –OH group of a carboxylic acid with
an amino group that may or may not be
Aldehyde Ketone substituted.

Carbonyl Group: C=O. Aldehydes and ketones both have a carbonyl
group.
Aldehyde: Carbonyl group on terminal C.
Ketone: Carbonyl group on nonterminal C.

Primary, Secondary, and Tertiary
1° 2° 3°
Alcohols:

Amines:

13
 Organic Chemistry 2: Isomers
Structural Isomers Relative & Absolute Configuration
Share only a molecular formula. Relative Configuration: Gives the stereochemistry of a compound in
Have different physical and chemical properties. comparison to another compound. E.g. D and L.
Absolute Configuration: Gives the stereochemistry of a compound
without having to compare to other compounds.
E.g. S and R.
Compounds with atoms connected in the
Stereoisomers same order but differing in 3D orientation. Cahn-Ingold-Prelog Priority is given by looking at atoms connected to
Priority Rules: the chiral carbon or double-bonded carbons;
Chiral Center: Four different groups attached to a central carbon. whichever has the highest atomic # gets highest
priority.
2n Rule: 𝑛 = # of chiral centers # of stereoisomers = 23
(Z) and (E) for Alkenes: (Z): Highest priority on same side.
Conformational Isomers (E): Highest priority on opposite sides.
(R) and (S) for A stereocenter’s configuration is determined by
Stereocenters: putting the lowest priority group in the back and
drawing a circle from group 1-2-3.
(R): Clockwise
(S): Counterclockwise
Fischer Projection: Vertical lines go to back of page (dashes);
Anti Gauche Eclipsed horizontal lines come out of the page (wedges).

Differ by rotation around a single (s) bond
Cyclohexane Equatorial: In the plane of the molecule.
Substituents: Axial: Sticking up/down from the molecule’s plane.
Configurational Isomers

Altering Fischer Switching 1 pair of substituents inverts the
Projection: stereochemistry; switching 2 pairs retains
stereochemistry. Rotating entire diagram 90°
inverts the stereochemistry; rotating 180°
retains stereochemistry.

Enantiomers
Enantiomers: Nonsuperimposable mirror images. Opposite
stereochemistry at every chiral carbon. Same
chemical and physical properties, except for
rotation of plane polarized light.
Optical Activity: The ability of a molecule to rotate plane-polarized
light: d- or (+) = RIGHT, l- or (-) = LEFT.
Racemic Mixture: 50:50 mixture of two enantiomers. Not optically
active because the rotations cancel out.
Meso Compounds: Have an internal plane of symmetry, will also be
optically inactive because the two sides of the
molecule cancel each other out.

Diastereomers
Diastereomers: Stereoisomers that are NOT mirror image.
Cis-Trans: A subtype of diastereomers. They differ at some,
but not all, chiral centers. Different chemical and
physical properties.

14
Organic Chemistry 3: Bonding

Atomic Orbitals & Quantum Numbers Hybridization
Quantum Numbers: Describe the size, shape, orientation, and number sp3: 25% s character and 75% p character
of atomic orbitals in an element Tetrahedral geometry with 109.5° bond angles
Quantum Possible sp2: 33% s character and 67% p character
Name What it Labels Notes
Number Values
Trigonal planar geometry with 120° bond angles
n Principal e- energy level or
shell number
1, 2, 3, … Except for d-orbitals, the shell
# matches the row of the
periodic table sp: 50% s character and 50% p character
l Azimuthal 3D shape of orbital 0, 1, 2, …, n-1 0 = s orbital Linear geometry with 180° bond angles
1 = p orbital
2 = d orbital Resonance: Describes the delocalization of electrons in
3 = f orbital
4 = g orbital
molecules that have conjugated bonds
ml Magnetic Orbital sub-type Integers
–l ® +l
Conjugation: Occurs when single and multiple bonds alternate,
" " creating a system of unhybridized p orbitals down
ms Spin Electron spin
+ ,−
# # the backbone of the molecule through which p
electrons can delocalize
Maximum e- in terms of n = 2n2
Maximum e- in subshell = 4l + 2

Molecular Orbitals
Bonding Orbitals: Created by head-to-head or tail-to-tail overlap of
atomic orbitals of the same sign. ¯energy ­stable
Antibonding Orbitals: Created by head-to-head or tail-to-tail overlap of
atomic orbitals of opposite signs. ­energy ¯stable

Single Bonds: 1 s bond, contains 2 electrons
Double Bonds: 1 s + 1 p
Pi bonds are created by sharing of electrons
between two unhybridized p-orbitals that align
side-by-side
Triple Bonds: 1 s + 2 p
Multiple bonds are less flexible than single bonds because rotation is not
permitted in the presence of a p bond. Multiple bonds are shorter and
stronger than single bonds, although individual p are weaker than s bonds

15
 Organic Chemistry 4: Analyzing Organic Reactions

Acids and Bases REDOX Reactions
Lewis Acid: e- acceptor. Has vacant orbitals or + polarized atoms. Oxidation Number: The charge an atom would have if all its bonds were
completely ionic.
Lewis Base: e- donor. Has a lone pair of e-, are often anions.
Oxidation: Raises oxidation state. Assisted by oxidizing agents.
Brønsted-Lowry Acid: Proton donor
Oxidizing Agent: Accepts electrons and is reduced in the process.
Brønsted-Lowry Base: Proton acceptor
Reduction: Lowers oxidation state. Assisted by reducing agents.
Amphoteric Can act as either acids or bases, depending on
Molecules: reaction conditions. Reducing Agent: Donates electrons and is oxidized in the process.

Ka: Acid dissociation constant. A measure of acidity. It is
the equilibrium constant corresponding to the
dissociation of an acid, HA, into a proton and its
conjugate base. Chemoselectivity
pKa: An indicator of acid strength. pKa decreases down the Both nucleophile-electrophile and REDOX reactions tend to
periodic table and increases with EN. act at the highest-priority (most oxidized) functional group.
p𝐾# = −log (𝐾# )
One can make use of steric hindrance properties to
a-carbon: A carbon adjacent to a carbonyl. selectively target functional groups that might not primarily
react, or to protect functional groups.
a-hydrogen: Hydrogen connected to an a-carbon.

SN 1 SN2 E1 E2

Solvents
Nucleophiles, Electrophiles and Leaving Groups
Polar Protic Polar Aprotic
Nucleophiles: “Nucleus-loving”. Contain lone pairs or p bonds. They have
Polar Protic solvents Polar Aprotic solvents
­EN and often carry a NEG charge. Amino groups are
Acetic Acid, H2O, DMF, DMSO,
common organic nucleophiles.
ROH, NH3 Acetone, Ethyl Acetate
Nucleophilicity: A kinetic property. The nucleophile’s strength. Factors that
affect nucleophilicity include charge, EN, steric hindrance,
and the solvent.
Electrophiles: “Electron-loving”. Contain a + charge or are positively
polarized. More positive compounds are more electrophilic.
Substrate Polar Protic Polar Aprotic Strong Small Strong Bulky
Leaving Group: Molecular fragments that retain the electrons after
heterolysis. The best LG can stabilize additional charge Solvent Solvent Base Base
through resonance or induction. Weak bases make good LG. Methyl
SN1 Reactions: Unimolecular nucleophilic substitution. 2 steps. In the 1st SN2 SN2 SN2 SN2
step, the LG leaves, forming a carbocation. In the 2nd step,
the nucleophile attacks the planar carbocation from either
side, leading to a racemic mixture of products. Primary
Rate = 𝑘 [substrate] SN2 SN2 SN2 E2
SN2 Reactions: Bimolecular nucleophilic substitution. 1 concerted step. The
Secondary
nucleophile attacks at the same time as the LG leaves. The
nucleophile must perform a backside attack, which leads to SN1 / E1 SN2 E2 E2
inversion of stereochemistry. (R) and (S) is also changed if
the nucleophile and LG have the same priority level. SN2
prefers less-substituted carbons because steric hindrance Tertiary
inhibits the nucleophile from accessing the electrophilic SN1 / E1 SN1 / E1 E2 E2
substrate carbon.
Rate = 𝑘 [nucleophile] [substrate]

16
Organic Chemistry 5: Alcohols

Description & Properties Reactions of Alcohols
Alcohols: Have the general form ROH and are named with the suffix –ol. Primary Can be oxidized to aldehydes only by pyridinium
If they are NOT the highest priority, they are given the prefix Alcohols: chlorochromate (PCC); they will be oxidized all the way to
hydroxy- carboxylic acids by any stronger oxidizing agents
Phenols: Benzene ring with –OH groups attached. Named for the relative Secondary Can be oxidized to ketones by any common oxidizing agent
position of the –OH groups: Alcohols:
Alcohols can be converted to mesylates or tosylates to make them better
leaving groups for nucleophilic substitution reactions
Mesylates: Contain the functional group –SO3CH3
ortho meta Tosylates: Contain the functional group –SO3C6H4CH3
para
Alcohols can hydrogen bond, raising their boiling and melting
points
Phenols are more acidic than other alcohols because the
aromatic ring can delocalize the charge of the conjugate base Mesylate Tosylate
Electron-donating groups like alkyl groups decrease acidity
Aldehydes or ketones can be protected by converting them into acetals or
because they destabilize negative charges. EWG, such as EN
ketals
atoms and aromatic rings, increase acidity because they stabilize
negative charges Acetal: A 1° carbon with two –OR groups and an H atom
Ketal: A 2° carbon with two –OR groups

Acetal Ketal
Reactions of Phenols
Deprotection: The process of converting an acetal or ketal back to a
Quinones: Synthesized through oxidation of phenols. Quinones carbonyl by catalytic acid
are resonance-stabilized electrophiles. Vitamin K1
(phylloquinone) and Vitamin K2 (the menaquinones) are
examples of biochemically relevant quinones

Quinone
Hydroxyquinones: Produced by oxidation of quinones, adding a variable
number of hydroxyl gruops
Ubiquinone: Also called coenzyme Q. Another biologically active
quinone that acts as an electron acceptor in Complexes
I, II, and III of the electron transport chain. It is reduced
to ubiquinol

17
 Organic Chemistry 6: Aldehydes and Ketones I: Electrophilicity and Oxidation-Reduction

Description and Properties Nucleophilic Addition Reactions
Aldehydes: Are terminal functional groups containing a carbonyl bonded When a nucleophile attacks and forms a bond with a carbonyl carbon,
to at least one hydrogen. Nomenclature: suffix –al. In rings, electrons in the p bond are pushed to the oxygen atom. If there is no good
they are indicated by the suffix –carbaldehyde. leaving group (aldehydes and ketones), the carbonyl will remain open and
is protonated to form an alcohol. If there is a good leaving group
Ketones: Internal functional groups containing a carbonyl bonded to
(carboxylic acid and derivatives), the carbonyl will reform and kick off the
two alkyl chains. In nomenclature, they use the suffix –one
leaving group.
and the prefix oxo- or keto-.
Hydration Rxns: Water adds to a carbonyl, forming a geminal diol.
Carbonyl: A carbon-oxygen double bond. The reactivity of a carbonyl is
dictated by the polarity of the double bond. The carbon has a
d+ so it is electrophilic. Carbonyl containing compounds have a
­BP than equivalent alkanes due to dipole interactions. Aldehyde or Gem-diol
Alcohols have ­BP than carbonyls due to hydrogen bonding. Ketone
Oxidation: Aldehydes and ketones are commonly produced by oxidation Aldehyde + Alcohol: When one equivalent of alcohol reacts with an
of primary and secondary alcohols, respectively. Weaker, aldehyde, a hemiacetal is formed. When the same
anhydrous oxidizing agents like pyridinium chlorochromate rxn occurs with a ketone, a hemiketal is formed.
(PCC) must be used for synthesizing aldehydes, or the reaction
will continue oxidizing to a carboxylic acid. When another equivalent of alcohol reacts with a
hemiacetal (via nucleophilic substitution), an acetal
is formed. When the same reaction occurs with a
hemiketal, a ketal is formed.

1° Alcohol Aldehyde

Oxidation-Reduction Reactions
Aldehydes: Aldehydes can be oxidized to carboxylic acids using an
oxidizing agent like KMnO4, CrO3, Ag2O, or H2O2. They can be
reduced to primary alcohols via hydride reagents (LiAlH4,
NaBH4).
Ketones: Ketones cannot be further oxidized, but can be reduced to
secondary alcohols using the same hydride reagents.
Nitrogen + Carbonyl: Nitrogen and nitrogen derivatives react with
carbonyls to form imines, oximes, hydrazones, and
semicarbazones. Imines can tautomerize to form
Common Oxidizing / Reducing Agents