Analyzing Organic Reactions

Question 1

Lewis Acid

Answer 1

electron acceptor in the formation of a covalent bond
-tend to be electrophiles
-have vacant p-orbitals which can accept an electron pair, or are positively polarized atoms

Question 2

Lewis Base

Answer 2

electron donor in the formation of a covalent bond
-tend to be nucleophiles
-have a lone pair of electrons that can be donated and are often anions

Question 3

coordinate covalent bonds

Answer 3

form when lewis acids and bases interact
-electrons in the bond come from the same starting atom (the Lewis base)

Question 4

Bronsted-Lowry acid

Answer 4

proton donor

Question 5

amphoteric

Answer 5

ability to act as either Bronsted-Lowry acid or base (e.g. water, Al(OH)3, HCO3−, and HSO4−)

Question 6

Al(OH)3

Answer 6

aluminum hydroxide,

acts as base:
3 HCl + Al(OH)3 → AlCl3 + 3 H2O

acts as acid:
Al(OH)3 + OH− → Al(OH)4−

Question 7

Bronsted-Lowry base

Answer 7

proton acceptor

Question 8

acid dissociation constant (ka)

Answer 8

measures the strength of an acid in solution

Question 9

Ka equation

Answer 9

In the dissociation of an acid HA (HA ⇋ H+ + A-), the equilibrium constant is given by:

Question 10

pKa

Answer 10

-logKa
-the lower the pKa the stronger the acid
-some pKa can be negative

Question 11

strong acid

Answer 11

pKa below -2

Question 12

weak acid

Answer 12

pka between -2 and 20

Question 13

pKa values for common functional groups

Answer 13

acidity increases with decreasing bond strength to H.

The more electronegative the atom, the higher the acidity

When the above two trends oppose each other, low bond strength takes precedence.

Question 14

functional groups that act like acids:

Answer 14

alcohols, aldehydes, ketones (at the lphaa-carbon), carboxylic acids, and most carboxylic acid derivatives.

Easier to target basic or nucleophilic reactants because they accept a lone pair

Question 15

functional groups that act like bases:

Answer 15

amines, amides. N can form coordinate covalent bonds by donating a lone pair to a Lewis acid

Question 16

Nucleophile

Answer 16

defined as nucleus loving species, with either lone pairs or pi bonds that can form new bonds to electrophiles

Question 17

Difference between nucleophile strength and base strength

Answer 17

nucleophile strength: is based on the relative rates of reaction with a common electrophile, so it is a kinetic property.
base strength: related to the equilibrium position of the reaction and is therefore a thermodynamic property

good nucleophiles tend to be good bases
the more basic a nucleophile, the more reactive it is

Question 18

Four factors that determine nucleophilicity

Answer 18

1. charge: nucleophilicity increases with increasing electron density (more negative charge)
2. electronegativity: nucleophilicity decreases as electronegativity increases since these atoms are less likely to share their electron density
3. steric hindrance: bulkier molecules are less nucleophilic
4. solvent: protic (hydrogen attached to an oxygen or nitrogen) solvents can hinder nucleophilicity by protonating the nucleophile or through hydrogen bonding

Question 19

in polar protic solvents, nucleophilicity ________ down the periodic table

Answer 19

increases

-protons in solution will attract nucleophile, instead of electrophile attracting nucleophile
In order from most nucleophilic to least nucleophilic
I-, Br-, Cl-, F-

Question 20

in aprotic solvents, nucleophilicity ________ as you go up the periodic table

Answer 20

increases

-no protons get in the way of the attacking nucleophile. in these solutions, the nucleophilicity relates directly to basicity
In order from most nucleophilic to least nucleophilic:
F-, Cl-, Br-, I-

Question 21

Examples of polar protic and polar aprotic solvents

Answer 21

Question 22

can you use a nonpolar solvent in a nucleophile-electrophile reaction?

Answer 22

no since the reactants are polar. in a nonpolar solvent they would not dissolve

Question 23

Examples of strong nucleophiles

Answer 23

HO-, RO-, CN-, N3-. Amine groups tend to be good nucleophiles

Question 24

examples of fair nucleophiles

Answer 24

NH3, RCO2-

Question 25

examples of weak nucleophiles

Answer 25

H2O, ROH, RCOOH

Question 26

electrophiles

Answer 26

“Electron-loving” atoms with a positive charge or positively polarized atom that accepts an electron pair when forming bonds with a nucleophile
-almost always act as lewis acid in reaction

Question 27

comparisons of electrophilicity of carboxylic acid derivatives

Answer 27

anhydrides are most reactive, followed by carboxylic acids and esters, then amides
-derivatives of higher reactivity can form derivatives of lower reactivity, but not vice versa

Question 28

leaving groups

Answer 28

the molecular fragments that retain the electrons after heterolysis, where a bond is broken and both electrons are given to one of the two products.

-the best leaving group will be able to stabilize extra electrons. Resonance and inductive effects from electron withdrawing groups can stabilize negative charge.
-weak bases make good leaving groups (conjugate bases of strong acids, like I-,Br-, Cl-)
-alkanes and hydrogen ions will almost never serve as leaving groups since they form very reactive and strong basic anions
-Another way to think about leaving group: the weaker the base is the leaving group while the stronger base (nucleophile) replaces the weaker base

Question 29

heterolytic reactions

Answer 29

opposite of coordinate covalent bond formation: a bond is broken and both electrons are given to one of the two products.

Question 30

Nucleophilic substitution

Answer 30

A type of substitution reaction in which a nucleophile is attracted to an electron-deficient center or atom, where it donates a pair of electrons to form a new covalent bond.

the nucleophile must be more reactive than the leaving group, otherwise leaving group will attach right back.

Question 31

Unimolecular nucleophilic substitution (SN1) reactions

Answer 31

Step 1: leaving group leaves and is the rate-limiting step. this generates a positively charged carbocation
Step 2: nucleophile attacks the carbocation

the more substituted the carbocation, the more stable it is because the alkyl groups act as electron donors which stabilize the positive charge, so SN1 only occurs for secondary or tertiary carbon

since first step is rate limiting step, the rate of reaction only depends on substrate: rate-k[R-L], where L is leaving group.
-anything that accelerates the formation of the carbocation will increase the rate of SN1 reaction

usually yield racemic mixture since the incoming nucleophile can attack the carbocation from either side

Question 32

Mechanism of SN1 Reaction

Answer 32

Question 33

bimolecular nucleophilic substitution (Sn2)

Answer 33

reactions contain only one step (concerted reaction): the nucleophile attacks the compound at the same time as the leaving group leaves’
-cause an inversion of absolute configuration (S and R will switch)

Question 34

Mechanism of SN2 Reaction

Answer 34

Question 35

stereospecific reaction

Answer 35

configuration of the reactant determines the configuration of the products due to the reaction mechanism

Question 36

oxidation-reduction reaction

Answer 36

any chemical change in which one species is oxidized (loses electrons) and another species is reduced (gains electrons)

Question 37

oxidation state

Answer 37

an indicator of the hypothetical charge that an atom would have if all bonds were completely ionic

Question 38

oxidation

Answer 38

refers to the increase in oxidation state, which means a loss of electrons

Question 39

reduction

Answer 39

refers to the decrease in oxidation state, which means gaining of electrons (increasing the number of bonds to hydrogen or removal of bonds to O)

Question 40

functional groups from least to most oxidized

Answer 40

Level 0 (no bonds to heteroatoms): alkanes

Level 1 (1 bond to heteroatoms): alcohols, alkyl halides, amines

Level 2 (2 bonds to heteroatoms): aldehydes, ketones, imines

Level 3 (3 bonds to heteroatoms): carboxylic acids, anhydrides, esters, amides

Level 4 (four bonds to heteroatoms): carbon dioxide

Note that oxidation is in reference to the C atom

Question 41

oxidizing agent

Answer 41

element or compound in a redox reaction that accepts an electron from another species
-it is reduced
-good oxidizing agents have a high affinity for electrons or high oxidation states

Question 42

Oxidation of alcohols

Answer 42

Primary alcohols can be oxidized by one level to become aldehydes, or can be further oxidized to form carboxylic acids.

Question 43

reduction of carbon atom

Answer 43

when a bond between a carbon atom and an atom that is more electronegative than carbon is replaced by a bond to an atom that is less electronegative than carbon.

Question 44

good reducing agents

Answer 44

sodium, magnesium, aluminum, and zinc, metal hydrides (NaH, CaH2, LiAlH4, and NaBH4 since they contain the H- ion)

Question 45

Chemoselectivity

Answer 45

preferential reaction of one functional group in the presence of another functional group

Nucleophilic-eletrocphilic reactions occur on the highest priority functional group since it usually contains the most oxidized carbon.
Nucleophile is looking for electrophile (positive partial charge on C).
Aldehydes generally more reactive toward nucleophiles than ketones because they are less sterically hindered

Question 46

common reactive site: the carbon of a carbonyl

Answer 46

-found in carboxylic acid and its derivatives, ketones, and aldehydes
-Carbon acquires a positive polarity due to the electronegativity of the oxygen. Carbonyl carbon becomes electrophilic and can be targeted by nucleophiles
-alpha- Hydrogens are much more acidic than in a regular C-H bond. This occurs due to resonance stabilization of the enol form after H is pulled off. These can be deprotonated easily with a strong base which would form an enolate.
Enolate then becomes a strong nucleophile and alkylation can result if good electrophiles available.

Question 47

steric hindrance

Answer 47

describes the prevention of reactions at a particular location within a molecule due to the size of substituent groups

Question 48

steric protection

Answer 48

The Prevention of the formation of alternative products using a protecting group such as a mesylate or tosylate.

Question 49

protecting group

Answer 49

uses sterics to protect leaving groups.

Question 50

Steps in Problem Solving

Answer 50

1. know your nomenclature
2. identify the functional groups
3. identify the other reagents
4. identify the most reactive functional group (s): more oxidized C tend be more reactive to both nucleophile-electrophile interactions and redox reactions.
5. identify the first step of the reaction (ex: HOCH2CH2OH is commonly used as protecting group)
6. consider stereoselectivity