Dr. Collins Organic Chemistry 1

Single Bond

1 sigma bond

form: formaldehyde

H₂CO

monounsaturated

one double bond

Elements of Unsaturation

Compounds with double bonds, triple bonds, or rings have less than 2n+2 hydrogens Each element of unsaturation is 2 H's less than the maximum 2n+2 (i.e. 2H = 1 element of unsaturation) Double Bond = 1 element of unsaturation Triple Bond = 2 elements of unsaturation Ring = 1 element of unsaturation C₆H₁₀ 2(6)+2=14 → 14-10=4 → 2 elements of unsaturation → 2 DB, 1 TB, or 1 DB + 1 ring

Cause of Combustion

Compounds with low BP (hydrocarbons/non-polar organic compounds) have high vapor or at gases at room temperature, making them flammable/explosive/combustible

Hybridization of Two-Dimensional (Flat) Molecules

Contain only sp and/or sp² atoms (other than H)

Elements of Unsaturation for Formulas containing Halogens

Halogens (F, Cl, Br, I) form single bonds like H; replace halogens with H and calculate elements of unsaturation C₂H₂Cl₄ = C₂H₆ 2(2)+2=6 → no unsaturations

Sigma Bond

Head-on overlap of atomic (s, p) or hybrid (sp, sp², sp³) orbitals

Electrophile

Lewis Acid (electron acceptor)

Nucleophile

Lewis Base (electron donor with formation of a bond)

Solubility

Like dissolves like

aldehyde

R- CHO oxygen and carbon are double bond

ester

R- CO₂- R'

carboxylic acid

R- CO₂H or R- COOH

Electronic Geometry

Shape of molecule described by the bonded and unshared electrons

Molecular Geometry

Shape of molecule without lone pairs of electron

Pi Bond

Side-to-Side overlap of p orbitals

Conjugate Base Stability

Strong acids ionize readily; the stronger the acid, the more stable (less reactive) the conjugate base Conjugate base stability can be due to: 1. higher EN of atom in conjugate base 2. larger size 3. resonance stabilization

radical

a species with an unpaired electron

two dimensional sharp

benzene

imine

carbon and nitrogen double bond

azide

liner 180 degree

diatomic

molecules that exist as two atoms covalently bonded together

Polyunsaturated

more than one double bond

Saturated

no double bonds higher melting point than unsaturated fatty acid

the rutherford Gold Foil

nuclear structure of atom

Unsaturated fatty acids

one or more double bond

ketogenesis

produce ketone in bodies that take place in the liver under fasting condition. Fatty acids to B oxidization --> Acetyl-CoA--> Ketone

Alkyne

triple carbon bond

addition reaction

double bond become single bond

Alkene

double carbon bond

DNA

form by hydrogen bond

zwitterion

formerly called a dipolar ion, is a neutral molecule with both positive and negative electrical charges

longer hydrocarobon chain

higher melting point

Bonding Characteristics of Carbon

Carbon always obeys octet rule in neutral molecules

hydration

OH came from water

Double Bond

1 sigma + 1 pi bond Each atom involved has a sp² orbital (forms sigma bond) and a p orbital (forms pi bond)

Triple Bond

1 sigma + 2 pi bonds Each atom involved has a sp orbital (forms sigma bond) and 2 p orbitals (forms pi bonds)

amides

1° R- C -NH2 // O 2° R- C -NH -R' / / O 3° R - C- N -R -R'

amines

1° R-NH₂ 2° R-NH 3° R-N-R' - R''

Dehydration most easily

3°>2°>1°

Hydrogen Bonds

Attraction between positive H and negative O, N, or F Molecules with -OH or -NH groups (or the molecule HF) can hydrogen bond

Boiling Point Trends

BP increases with number of C (increasing MW or molar mass) A molecule with a more polar group (or more EN atom) will have a higher BP Groups that can hydrogen bond will increase the BP the most

Elimination Reaction

Base accepts proton Acid donates proton

aniline

BenzeneR-NH2

Acid

Bronsted-Lowry Acid (proton donor)

Base

Bronsted-Lowry Base (proton acceptor)

General Formula for Alkane

C(n)H(2n+2)

saturated formular CnH2nO2

C16H32O2 saturated fatty acid

SN2

CH₃ CH-CH₂ Cl (secondary degree Alkyl Halide)

SN1

CH₃ CH₂ F Alkyl Halide (1 degree)

SN3

CH₃ CH₃ - C- CH₃ - Tertiary

Halide

CH₃ I

fastest reaction

CH₃X > 1 degree > 2 degree >>> 3 degree

esterification

Carboxylic acid + alcohol → Ester + Water

multiple proportions

Co/C02 diiference in O

loss 2 Hydrogen ethane

Ethene

ferrous

Fe²⁺

ferric

Fe³⁺

Influence of Shape/Polarity on Physical Properties

More symmetrical/less polar molecules have lower BP More symmetrical molecules pack more tightly together, requiring more energy to melt → higher MP trans-alkenes have lower BP and higher MP than cis-alkenes

Bonding Characteristics of Nitrogen and Oxygen

N and O always obey octet rule and complete their octets with lone pairs of electrons

Substitution Reaction

Nucleophile donates electron and forms bond Electrophile accepts electron

Bond Length

The more s character an orbital has, the shorter the bond H-H < triple bond < double bond < single bond s-s sp-sp sp²-sp² sp³-sp³

Hydration reaction

reactant no water but product has water

Neutralization reaction

reaction between an acid and base to form salt and water

Dehydration

reaction which net overall elimination of water

metathesis reaction

reactions in which ions are exchanged

dehydration reaction

single bond to double bond

alkane

single carbon bond

Geometry of sp Hybridization

sp linear (180°)

Geometry of sp² Hybridization

sp² trigonal planar (120°)

Geometry of sp³ Hybridization

sp³ tetrahedral (109.5°)

best leaving group Sn2 reaction

weak base