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sp³ hybridization: tetrahedral, 109.5°
Alkanes, saturated carbons
4 σ bonds, no π bonds
sp² hybridization: trigonal planar, 120°
Alkenes, carbonyls, aromatics
3 σ bonds + 1 π bond
sp hybridization: linear, 180°
Alkynes, allenes, nitriles
2 σ bonds + 2 π bonds
Bond energies (approximate):
C-C: 347 kJ/mol C=C: 614 kJ/mol
C-H: 413 kJ/mol C-O: 358 kJ/mol
C-N: 305 kJ/mol C=O: 745 kJ/mol
C-Cl: 339 kJ/mol O-H: 463 kJ/mol
Electronegativity (Pauling):
F: 4.0, O: 3.5, N: 3.0, Cl: 3.0, Br: 2.8
C: 2.5, H: 2.1, Si: 1.8, Na: 0.9
Resonance:
Delocalization of electrons across adjacent p orbitals
More resonance structures → more stable molecule
Carboxylate, amide, phenol all stabilized by resonance
SN2 (Substitution Nucleophilic Bimolecular):
One step: backside attack, simultaneous bond breaking/forming
Rate = k[Nu][substrate] (second order)
Inversion of configuration (Walden inversion)
Favored by:
- Primary substrates (less steric hindrance)
- Strong, unhindered nucleophiles (OH⁻, CN⁻, I⁻, RS⁻)
- Polar aprotic solvents (DMSO, DMF, acetone)
- Good leaving groups (I > Br > Cl >> F)
SN1 (Substitution Nucleophilic Unimolecular):
Two steps: ionization → carbocation → nucleophile attack
Rate = k[substrate] (first order)
Racemization (achiral carbocation attacked from both faces)
Favored by:
- Tertiary > Secondary substrates (stable carbocation)
- Weak nucleophiles (H₂O, ROH)
- Polar protic solvents (H₂O, ROH) stabilize ions
- Good leaving groups
Nucleophilicity vs Basicity:
Nucleophilicity: kinetic, attacks carbon
Basicity: thermodynamic, attacks proton
In protic solvents: I⁻ > Br⁻ > Cl⁻ > F⁻ (nucleophilicity)
In aprotic solvents: F⁻ > Cl⁻ > Br⁻ > I⁻ (reverses!)
Leaving group ability:
Good LG: stable after departure
I⁻ > Br⁻ > Cl⁻ > F⁻
TsO⁻ > I⁻ (tosylate excellent LG)
OH⁻ is poor LG (must protonate to make H₂O)
E2 (Elimination Bimolecular):
Concerted: base removes β-H, π bond forms, LG leaves
Rate = k[base][substrate]
Anti-periplanar geometry required (dihedral 180°)
Zaitsev product: more substituted alkene (thermodynamic)
Hofmann product: less substituted (bulky base, E1cb)
Favored by: strong base, high T, secondary/tertiary
E1 (Elimination Unimolecular):
Two steps: carbocation formation → deprotonation
Rate = k[substrate] (same as SN1)
Zaitsev product predominates
Favored by: tertiary, weak base, protic solvent
E1cb:
Carbanion intermediate: deprotonation first, then LG leaves
Favored when: β-H especially acidic, poor LG
Competition: SN1/SN2/E1/E2
Primary + strong Nu + aprotic → SN2
Primary + strong base → E2 (if bulky base)
Secondary + strong base → E2
Tertiary + strong base → E2
Tertiary + weak Nu/base + protic → SN1/E1
Electrophilic addition to alkenes:
Markovnikov's rule: H adds to less substituted carbon
(more substituted carbocation intermediate is more stable)
HX addition: Markovnikov, forms haloalkane
H₂O/H⁺: Markovnikov, forms alcohol (acid-catalyzed hydration)
Halogens (Br₂, Cl₂): anti addition via cyclic halonium ion
Hypohalous acid (HOX): Markovnikov for X, anti addition
Oxymercuration-demercuration: Markovnikov, anti-Markovnikov possible
Hydroboration-oxidation: anti-Markovnikov, syn addition
Radical addition:
HBr + peroxides: anti-Markovnikov
Br adds to less substituted carbon (more stable radical)
Cycloadditions:
Diels-Alder [4+2]: diene + dienophile → cyclohexene
Syn addition, stereospecific (endo rule)
Diene must be s-cis conformation
Electron-rich diene + electron-poor dienophile (FMO theory)
[2+2]: photochemical conditions only (orbital symmetry)
Hydrogenation:
H₂ + catalyst (Pd/C, PtO₂, Raney Ni)
Syn addition of H₂ across π bond
Alkyne → alkene (Lindlar catalyst: cis) or trans (Na/NH₃)
Chirality:
Chiral center: carbon with 4 different substituents
Enantiomers: non-superimposable mirror images
Diastereomers: stereoisomers that are NOT mirror images
R/S Configuration (CIP rules):
1. Assign priorities by atomic number (high = 1)
2. Orient lowest priority away from viewer
3. Read remaining 1→2→3:
Clockwise = R (Rectus)
Counterclockwise = S (Sinister)
E/Z Configuration (alkenes):
Assign priorities on each carbon
Same side = Z (zusammen), opposite = E (entgegen)
Optical activity:
(+) or d: rotates plane of polarized light clockwise
(-) or l: rotates counterclockwise
[α] = α/(c·l) (specific rotation, c in g/mL, l in dm)
Racemic mixture (50:50 R/S): optically inactive
Meso compounds:
Multiple stereocenters but internally symmetric → achiral
Example: meso-tartaric acid (2R,3S)
Fischer projections:
Horizontal bonds come toward viewer
Vertical bonds go away from viewer
Cyclohexane conformations:
Chair most stable: axial and equatorial positions
Large groups prefer equatorial (less 1,3-diaxial strain)
Trans-1,4 disubstituted: both equatorial possible (stable)
Cis-1,4 disubstituted: one axial always (less stable)
Carbonyl reactivity:
C=O is polar: δ+ on C, δ- on O
Nucleophiles attack electrophilic carbon
Relative reactivity: acid chloride > anhydride > aldehyde > ketone > ester > amide
Nucleophilic addition to aldehydes/ketones:
Nu⁻ attacks C, then protonation
H₂O: gem-diol (hydrate)
ROH: hemiacetal → acetal (with H⁺ catalyst)
RMgX (Grignard): alcohol (add then protonate)
NaBH₄: reduce to alcohol (mild)
LiAlH₄: reduce to alcohol (strong)
RCN⁻: cyanohydrin
Acyl substitution (acid derivatives):
Nucleophile attacks C=O → tetrahedral intermediate → LG leaves
Always substitution (not addition) for acid derivatives
Relative LG ability: Cl⁻ > RCOO⁻ > RO⁻ > NR₂⁻ > H⁻
Convert: acid chloride → ester → amide (descending reactivity)
Enolate chemistry:
α-carbon deprotonation: pKa ~20 (ketone), ~25 (ester)
Strong base (LDA, NaH): kinetic enolate
Weak base (NaOH, NaOEt): equilibrium enolate
Alkylation: enolate + alkyl halide
Aldol reaction: enolate + carbonyl → β-hydroxy carbonyl
Aldol condensation:
Base: enolate attacks another carbonyl → aldol product
Heat: dehydration → α,β-unsaturated carbonyl (conjugated)
Mixed aldol: use preformed enolate + different aldehyde
Intramolecular: ring-forming (Haworth synthesis)
Claisen condensation:
Ester + base → β-ketoester
Dieckmann: intramolecular Claisen → cyclic β-ketoester
Aromaticity (Hückel rule):
Cyclic, planar, fully conjugated, 4n+2 π electrons
Benzene: 6π electrons (n=1) ✓
Cyclopentadienyl anion: 6π ✓
Tropylium cation: 6π ✓
Cyclooctatetraene: 8π (antiaromatic! n=1 for 4n)
Electrophilic Aromatic Substitution (EAS):
Mechanism: E⁺ attacks ring → arenium ion → deprotonation
Halogenation: ArH + X₂/FeX₃ → ArX + HX
Nitration: ArH + HNO₃/H₂SO₄ → ArNO₂
Sulfonation: ArH + SO₃/H₂SO₄ → ArSO₃H (reversible)
Friedel-Crafts alkylation: ArH + RX/AlCl₃ → ArR
Friedel-Crafts acylation: ArH + RCOCl/AlCl₃ → ArCOR
Directing effects:
ortho/para directors (activate ring):
-OH, -OR, -NR₂, -NHR, -NH₂ (strong activators)
-R, -Ph (weak activators)
-X (halogens: deactivate but o/p direct via lone pairs)
meta directors (deactivate ring):
-NO₂, -CN, -COOH, -COR, -SO₃H, -CF₃, -NR₃⁺
Nucleophilic Aromatic Substitution (NAS):
Requires electron-withdrawing groups ortho/para to LG
Addition-elimination mechanism (Meisenheimer complex)
Benzyne mechanism at high T (elimination-addition)
def ir_spectroscopy():
return {
'O-H stretch': '3200-3550 cm⁻¹ (broad, alcohol)',
'N-H stretch': '3300-3500 cm⁻¹',
'C-H stretch': '2850-3000 cm⁻¹ (sp³), 3000-3100 (sp²)',
'C≡N stretch': '2200-2260 cm⁻¹',
'C≡C stretch': '2100-2260 cm⁻¹',
'C=O stretch': '1630-1870 cm⁻¹ (carbonyl fingerprint)',
'Aldehyde C=O': '1720-1740 cm⁻¹',
'Ketone C=O': '1705-1725 cm⁻¹',
'Ester C=O': '1735-1750 cm⁻¹',
'Amide C=O': '1630-1690 cm⁻¹',
'Acid C=O': '1700-1725 cm⁻¹ + broad OH',
'C=C stretch': '1620-1680 cm⁻¹',
'Aromatic C=C': '1450-1600 cm⁻¹',
'C-O stretch': '1000-1300 cm⁻¹',
'C-X stretch': '500-800 cm⁻¹'
}
def nmr_chemical_shifts():
return {
'TMS reference': '0 ppm',
'Alkyl CH₃': '0.9 ppm',
'Alkyl CH₂': '1.2-1.4 ppm',
'Allylic CH₂': '1.6-2.2 ppm',
'C=O adjacent CH': '2.0-2.5 ppm',
'N-CH': '2.2-2.9 ppm',
'O-CH₂ (ether)': '3.3-3.5 ppm',
'O-CH₂ (ester)': '3.7-4.1 ppm',
'Vinyl CH': '4.5-6.5 ppm',
'Aromatic CH': '6.5-8.5 ppm',
'Aldehyde CHO': '9.5-10 ppm',
'Carboxylic COOH': '10-12 ppm',
'OH (variable)': '1-5 ppm',
'NH (variable)': '1-8 ppm'
}
def mass_spectrometry():
return {
'M+': 'Molecular ion — gives MW',
'M+1': 'One ¹³C (1.1% per carbon)',
'M+2': 'Bromine (+2, ~1:1 ratio), Chlorine (+2, ~3:1)',
'Base peak': 'Most abundant fragment',
'Common losses': {
'-15': 'Loss of CH₃',
'-18': 'Loss of H₂O',
'-28': 'Loss of CO (aldehyde/ketone)',
'-29': 'Loss of CHO',
'-31': 'Loss of OCH₃',
'-45': 'Loss of OEt'
},
'McLafferty': 'γ-H transfer in carbonyl compounds'
}
def named_reactions():
return {
'Grignard': 'RMgX + carbonyl → alcohol (C-C bond formation)',
'Wittig': 'Ph₃P=CHR + carbonyl → alkene (no OH byproduct)',
'Diels-Alder': 'Diene + dienophile → cyclohexene [4+2]',
'Aldol': 'Enolate + carbonyl → β-hydroxy carbonyl',
'Claisen': 'Ester enolate + ester → β-ketoester',
'Michael': 'Nucleophile + α,β-unsaturated carbonyl (conjugate add)',
'Robinson annulation': 'Michael + Aldol → cyclohexenone',
'Beckmann': 'Oxime → amide (acid-catalyzed rearrangement)',
'Baeyer-Villiger': 'Ketone + peracid → ester/lactone',
'Fries': 'Phenol ester → hydroxyaryl ketone (Lewis acid)',
'Curtius': 'Acyl azide → isocyanate (rearrangement)',
'Hofmann': 'Amide + Br₂/NaOH → amine (lose CO)',
'Birch': 'Aromatic + Na/NH₃/ROH → 1,4-cyclohexadiene',
'Sharpless': 'Asymmetric epoxidation (Ti, tartrate)',
'Metathesis': 'Grubbs catalyst, olefin exchange',
'Heck': 'Pd-catalyzed C-C coupling (aryl halide + alkene)',
'Suzuki': 'Pd-catalyzed coupling (aryl halide + boronate)',
'Sonogashira': 'Pd/Cu coupling (aryl halide + terminal alkyne)',
'Swern': 'Oxalyl chloride/DMSO oxidation of alcohol → aldehyde',
'Jones': 'CrO₃/H₂SO₄ oxidation → ketone/acid',
'Ozonolysis': 'O₃ cleaves alkene → carbonyls'
}
Retrosynthesis: work backward from target to starting materials
Arrow convention: ⟹ means "can be made from"
Disconnection strategies:
1. Identify key bonds to form (C-C bonds most valuable)
2. Classify: C-C, C-O, C-N, C-X
3. Choose appropriate reaction
Common disconnections:
Alcohol ← Grignard addition, NaBH₄ reduction
Alkene ← Wittig, elimination, metathesis
Ester ← Fischer esterification, acid chloride + ROH
Amine ← reductive amination, amide reduction
C-C α to carbonyl ← aldol, Claisen, Michael
Cyclohexenone ← Robinson annulation
Cyclohexene ← Diels-Alder
Functional group interconversion (FGI):
Change FG to reveal better disconnection
Oxidation states: alcohol → aldehyde → acid
Protection: if multiple reactive FG present
Example retrosynthesis:
Target: PhCH₂CH(OH)CH₃
Disconnect C-C: PhCH₂⁻ + CH₃CHO OR PhCH₂MgBr + acetaldehyde
→ React PhCH₂Br with Mg, then add CH₃CHO
| Pitfall | Fix |
|---|---|
| Markovnikov confusion | H goes to carbon with MORE H (more substituted carbocation) |
| SN1 vs SN2 substrate | Primary → SN2, Tertiary → SN1/E1, Secondary → depends |
| Anti addition forgotten | Bromine addition gives anti product via halonium ion |
| R/S assignment errors | Always point lowest priority AWAY before reading direction |
| Enolate regioselectivity | LDA (−78°C, kinetic), NaOEt (thermodynamic enolate) |
| EAS directing confusion | Deactivating groups are meta directors (except halogens) |