chapter 2 strain and stability - yonsei
TRANSCRIPT
Strain and StabilityChapter 2
- Reactivity of a new molecule-Prediction of the lowest energy conformation of a new molecule--> a rapid evaluation of strains and stabilizing effects
2.1 Thermochemistry of stable molecules (strain and stability)
2.1.1 The concepts of internal stain and relative stability
Strain:
Is typically associated with a conformational distortion or nonoptimal bonding situation
relative to standard organic structures. The reference structure lacks the particular strain.
Internal energy:
It is the energy held or stored within a molecule. Part of this energy can be released when given an outlet such as a chemical reaction.
When a molecule has a higher potential energy (internal energy), it is less stable and/or more strained.
2.1.2 Types of energyGibbs free energy (ΔGo): It is change in ΔGo between two different chemical states that determines the position of equilibrium between these states.
A B←→
R = 4.184 kJ/molΔHo : enthalpy (kcal/mol)ΔSo : entropy (cal/mol·K)
Exergonic, when the Gibbs free energy of B is lower than A, spontaneous conversionEndergonic, when the Gibbs free energy of B is higher than A
Keq is influenced by temperature
Enthalpy (ΔHo): The change in enthalpy is defined as the change in heat between two different compositions of an ensemble of molecules at constant pressure if no work is done.
Exothermic, negative ΔHo
Endotherimic, positive ΔHo
Entropy (ΔSo): is a measure of the disorder of the system. -> degrees of freedom
the more degrees of freedom, the greater the entropy.
There are three different kinds of degrees of freedom: translational, rotational and
vibrational.
Translational and rotational refer to the translation of the molecule throughout space and tumbling of the molecule, respectively.
Vibrational refers to every kind of internal motion of the molecule, such as bond stretches, bond rotations and various forms of bond angle vibrations.
While entropy is certainly important for significant changes in chemical structure (such as cyclization), often when comparing two similar structures, the difference in entropies will be fairly small. Thus, ΔHo is mainly considered in reactions.
2.1.3 Bond dissociation energies
Is defined as ΔHo.
(bond strength)
Homolytic cleavage
A larger BDE implies a less stable radical.
1. F > OH > NH2, the larger the electronegativity difference, the stronger the bond.
2. Shorter bonds are stronger bonds; O-H > N-H> C-H
3. F > Cl > Br > I; move down the periodic table, the valence orbitals of X get progressively larger. The larger orbital size leads to a size mismatch with the carbon valence orbitals, and this weakens the bond by decreasing orbital overlap.
4. Hybridization
C(sp)-H > C(sp2)-H > C(sp3)-H, more s character in a hybrid orbital makes the group
more electronegative and decreases the bond length.
5. Resonance
PhCH2-H (88 kcal/mol) and CH2=CH-CH2-H (86 kcal/mol)
6. O-O bonds of peroxides: generally very weak
2.1.4 An introduction to potential functions and surfaces: bond stretches
X. + Y.
X-YAnharmonic oscillator
Vibrational energy states
E = (n + ½)hv (n=0, ZPE) frequency = v = 1/(2π) √ k/μk = force constantμ = reduced mass, (m1 +m2)/m1m2
Infrared spectroscopy
v = 1/(2π) √ k/μk = force constantμ = reduced mass, (m1 +m2)/m1m2
v = 1/λ = v/c = 1/(2πc) √ k/μWavenumber(cm-1)
frequency
C-C C=C C≡C450-500 cm-1 1617-1640 cm-1 2100-2260 cm-1
C=C-C=O C=O1690 cm-1 1730 cm-1
O O-
+less double character
k
m1 m2Hooke’s law
v = 1/(2π) √ k/μ
1)
3)
2)
wavenumber the largest the lowest middle
O
Cl R
O
MeO R
O
Me R
O-
+Cl R
O-
MeO R+
2.2 Thermochemistry of reactive intermediates2.2.1 Stability vs persistence
1. stable; thermodynamic notion <-> unstable
2. persistent; kinetic notion (kinetically inert) <-> labile (reactive)
참조
1,3-butadiene ethylenemore stable less stable <- extra orbital interaction between C2 and C3more labile less labile
HOMO energy (ethylene)HOMO energy (butadiene) > LUMO energy (ethylene)LUMO energy (butadiene) <
Π
Π*
ψ1
ψ2
ψ3
ψ4
1,3-butadiene ethylene
Stability: determined by the energies of all the filled orbitalsLability (reactivity): must consider the energy of HOMO or LUMO
2.2.2 Radicals
1. BDE; methane > ethane > propane > isobutane <- radical stability 3o > 2o > 1o > methyl
2. Allyl and benzyl radicals -> substantially stabilized (resonance effect)
rotation barrier ~ 15.7 kcal/mol (resonance structure)Allylic radicalIn many cases, radical species are unstable but in some cases there are stable radical species.
Commercially available
2.2.3 Carbocations
Hydride ion affinity (HIA), ΔHo
A larger HIA implies a less stable carbocation.
1. Heteroatom effects
stability: NH2CH2+ > HOCH2
+ > FCH2+
X-CH2+
..+X=CH2
Consider both inductive and resonance effects2. Hybridization effects
stability: sp3 > sp2 > spConsider electronegativity
vinyl cation and phenyl cation: ~287 kcal/mol HIAverse Ethyl cation ~ 273 kcal/mol, propyl cation ~266 kcal/mol HIA
propargyl cation ~270 kcal/mol verse allyl cation ~256 kcal/mol
3. Aromaticity and antiaromaticity
> >stability:
HIA 201 212 258aromatic antiaromaticnon-aromatic
resonance effect
4. Planarity and pyramidalizationCarbocation: planar
Ring constraints prevent the ion from achieving Planarity. But 3o cation
Planar but 2o cation
relatively small difference in HIVs (9 kcal/mol)
Lifetimes of carbocations
3o carbocations: 10-10 s in water2o carbocations: 10-12 s in water
In solution
Carbocations are formed in solution by SbF5 (Olah, 1994, Nobel Prize)
2.2.4 Carbanions
Stability of carbanions is related to pKa values.The smaller pKa value implies a stronger acid.
aromatic
anti-aromatic
2.3 Relationships between structure and energetics-basic conformational analysis
2.3.1 Acyclic systems-torsional potential surfaces
ethane butanerotation barrier: 3kcal/mol
t1/2 = ln2/k
Barrier height
Similar; consider size and bond length
Lower than C-C, lone pair < C-H
Allylic (A1,3) strain
2.3.2 Basic cyclic systems
Cyclic propane
115o larger than H-C-H (106o)
Bent bonds (sp4~sp5)
(sp~sp2)
C-C-C, more p character to reduce bond angle (sp 180o, sp2 120o, sp3 109.5o) -> C-H more s character -> more acidic than alkane C-H
Strain energy of cyclopropane: 27.5 kcal/mol (results from deviation of bond angles from normal values andeclipsing C-H interactions)
Cyclobutane and cyclopentane
puckered conformationsStrain energy: 26.5 kcal/mol
very small barrier(1.45 kcal/mol)
Strain energy: 6.2 kcal/mol
Two forms are very nearly equal in energy and they interconvert very rapidly (the barrier is < 2 kcal/mol)
1’2’
3’
4’
5’
NH
N
N
O
NH2N
O
H (OH)OH
HO
1'2'3'4'
5'
Cyclohexane
Newman projection
A value: ΔGo of two structures (axial and equatorial)
similarconsider size and bond length
Not much difference
H RR
H
RR
Conformational interconversion of cyclohexane
Larger rings
cyclodecane~ 3 kcal/mol more stable
Bicyclic ring systems
spiro: a molecule has two rings and two share only one carbon in common
Strain energy
2.4 Electronic effects
2.4.1 interactions involving π systems
Substitution on alkenes:The more substitution, the more stable; interaction of a filled π(CH3) orbital withthe π* orbital.
steric effect
π*
π(CH3)
Stability, CH2=CH2 < CH2=CHMe < cis-CHMe=CHMe < trans-CHMe=CHMe
< CMe2=CMe2 < CHMe=CMe2
trans-alkenes are more stable than cis-ones.
Hyperconjugation: no-bond resonance
H
HH
H
H+
HH
-
Conformations of substituted alkenes:Eclipsed conformers are more stable than staggered ones.
2 kcal/mol more stable although there is steric hindrance.
HH
eclipsed staggered
filled π(CH3)
filled π filled π
filled π(CH3)
Repulsive interactions between filled π(CH3) and filled π
H
Attractive interaction π∗
filled π(CH3)
Repulsive interactions
C1C2
C3
C2-C3: strengthenedC1-C2:weakened
Allylic (A1,3) strain
H3C R
H
HO CH3
VO(acac)3
tBu-OOHhydroxyl group directing
epoxidation
H3C R
H
HO CH3
O
90%
H3C R
H
HO CH3
O
R = H10%
+
eclipsed; more stable A1,3 strain
H3C R
H
HO CH3
H3C R
CH3
H OHR = CH3; ~90%R = TMS; ~98%
H3C R
OH
H3C H
the most stable conformer
acac: acetoacetate
Carbonyl compounds
1 kcal/mol more stable
1-methylallyl cation
Conjugation
steric effectpreferred
Diels-Alderrxn
5 kcal/mol more stable
Aromaticity
Planar, cyclic, fully conjugated π systems
(4n+2)π electrons: aromatic, 4nπ e-: antiaromatic
Homoaromatic: systems in which a stabilized cyclic conjugated system is formed by bypassing a saturated atom.
Homoaromatic
Ha Hb Ha Hb
6π e- 6π e-
μ = 0.8 D (HBr; 0.828 D)
Aromatic compounds: ring current, downfield shift at 1H NMR spectra
Hdownfield (~7 ppm)
HHH
HHH
HH
H
H
HHH
H
H
H
HH
6H: -3 ppm12H: 9.3 ppm
AntiaromaticityPlanar, cyclic, fully conjugated π systems
4nπ e-
not square but rectangular structure
Cyclobutadiene: antiaromatic
Cyclooctatetraene: non-aromatic nonplanar
Cl SbCl5+ SbCl6-
aromatic
ClSbCl5
extremely slow antiaromatic
H pKa = 16
Ph
Ph
Ph
Ph
Ph
Ph pKa = 50
antiaromatic
aromatic
2.4.2 Effects of multiple heteroatomsBond length effects
The more substitution, the more stable; interaction of a filled π(CH3) orbital withthe π* orbital.
C-O and C-N are shorter than C-C, leading to increased steric strain.C-S is significantly longer than C-C.
OO
Rno 1,3-diaxial interaction
2-position 5-position
Orbital effects
D CA
..D C
A-
+
D: donorslone pair > bonding pairs, F < O < N
A: acceptorsF > O > N
n
σ*
n -> σ* interaction
H3CO Cl
HHO Cl
H3C
HH
CH2FNH2
CH3OCH2Cl
antiperiplanar
one antiperiplanar two antiperiplanar interactions-> more stable conformer
Anomeric effect
Pyranose sugars substituted with an electron-withdrawing group such as halogen oralkoxy at C-1 are often more stable when substituent has an axial orientation rather than an equatorial one.
n -> σ* interaction
O OR
axial
axialequatorial
antiperiplanar
Example)