Organic Chemistry- Analyzing Organic Reactions

Question 1

In an acid-base reaction, what happens?

Answer 1

An acid and base react, resulting in the formation of the conjugagate base of the acid and the conjugate acid of the base.

Question 2

The acid base reaction procees as long as what?

Answer 2

The reactants are more reactive, or stronger, than the products that they form

Question 3

The lewis acid/base defintion concerns itself with what?

Answer 3

Transfer of electrons in the formation of coordinate covalent bands.

Question 4

The bronsted-lowry definition of acid/base concerns itself with what?

Answer 4

Proton transfer

Question 5

What is a Lewis acid?

Answer 5

An electron acceptor in the formation of a covalent bond

Question 6

Lewis acids tend to be _____ and have ____

Answer 6

Electrophiles

They have vacant p-orbitals into which they can accept an electron pair, or are positively polarized atoms.

Question 7

What is a Lewis base?

Answer 7

An electron donor in the formation of covalent bonds

Question 8

Lewis bases tend to be _____ and have _____.

Answer 8

Nucleophiles.

They have a lone pair of electrons that can be donated, and are often anions carrying a negative charge.

Question 9

When Lewis acids and bases interact, they form what?

Answer 9

Coordinate covalent bonds

Question 10

What are coordinate covalent bonds?

Answer 10

Both electrons in the bond came from the same starting atom (the Lewis base)

Question 11

What is the Bronsted-Lowry definition of an acid and base?

Answer 11

An acid is a species that can donate a proton (H+)

A base is a species that can a ccept a proton

Question 12

Water is ______ which means it has the ability to what?

Answer 12

Amphhoteric

The ability to act as either Bronsted-Lowry acids or bases

Question 13

Water can only act like a base in _____, and can only act like an acid in _______.

Answer 13

Act as a base in acidic solutions

And acid in basic solutions

Question 14

What are other examples of amphoteric molecules?

Answer 14

Al(OH)3
HCO3-
HSO4-

Question 15

What is the acid dissociation constant?

Answer 15

Ka, measures the strength of an acid in solution

Question 16

What equation is used to determine the acid dissocation constant of acid HA
HA H+ + A-

Answer 16

Ka = [H+][A-]/[HA]

Question 17

How do you find the pKa of an acid HA?

Answer 17

pKa = -logKa

Question 18

More acidic molecules will have _______ pKa, more basic molecules will have a __________ pKa

Answer 18

Smaller (or negative) pKa

Larger (positive) pKa

Question 19

Acids with a pKa below -2 are considered what?

Answer 19

Strong acids, which alwmost always dissociates completely in aqueaous solution

Question 20

Weak organic acids often have pKa values between _____ and _____pKa

Answer 20

-2 and 20

Question 21

What is the pKa of Alkane?

Answer 21

-50

Question 22

What is the pKa of alkene?

Answer 22

-43

Question 23

What is the pKa of hydrogen?

Answer 23

42

Question 24

What is the pKa of amine?

Answer 24

-35

Question 25

What is the pKa of alkyne?

Answer 25

25

Question 26

What is the pKa of Ester?

Answer 26

25

Question 27

What is the pKa of ketone/aldehyde?

Answer 27

20-24

Question 28

What is the pKa of alcohol?

Answer 28

17

Question 29

What is the pKa of water?

Answer 29

16

Question 30

What is the pKa of carboxylic acid?

Answer 30

4

Question 31

What is the pKa of hydronium ion?

Answer 31

-1.7

Question 32

Bond strength _____ down a periodic table?

Answer 32

Decreases

Question 33

Acidity _____ down a periodic table?

Answer 33

increases

Question 34

The more electronegative an atom, the higher _______.

Answer 34

The Acidity

Question 35

When electronegativity and bond strength oppose each other; to determine acidity, which takes precedence?

Answer 35

Low bond strength takes precedence

Question 36

What are alpha-hydrogens?

Answer 36

Hydrogens connected to the alpha-carbon

Question 37

What are alpha-carbons?

Answer 37

A carbon adjacent to the carbonyl

Question 38

Why are the alpha-hydrogens in a carbonyl compound easily lost?

Answer 38

Because the enol form of carbonyl-containing carbonions is stabilizd by resonance, these are acidic hydrogens that are easily lost.

Question 39

What are functional groups that act as acids?

Answer 39

Alcohols,
 aldehydes, 
ketones (at the alpha-carbon)
Carboxylic acids
Most carboxylic acid derivatives.

Question 40

The functional groups, that arc as acids, are easier to target with what? Why?

Answer 40

Basic (or nucleophilic reactants) because they readily accept a lone pair

Question 41

What functional groups act as bases?

Answer 41

Amines and Amides

Question 42

Amines and Amides will be seen in what bonds?

Answer 42

Peptide bonds.

The nitrogen atom of an amine can form coordinate covalent bonds by donating a lone pair to a Lewis acid

Question 43

What are the two groups of reactions in organic chemistry?

Answer 43

Oxidation-Reduction

Nucleophile-electrophile

Question 44

What is important to the reactions of alcohols and carbonyl-containing compounds?

Answer 44

Nucleophiles
electrophiles
Leaving groups

Question 45

What is the definition of nucleophiles?

Answer 45

Nucleus-loving species with either lone pairs or pi bonds that can form new bonds to electrophiles.

Question 46

What is the distinction between nucleophiles and bases?

Answer 46

Nucleophile strength is based on relative rates of reaction with a common electrophile– and therefore a kinetic property. Base strength is related to the equilibirum postion of a reaction– and therefore a thermodynamic property.

Question 47

What are some common examples of nucleophiles?

Answer 47

Anions
pi bonds
Atoms with lone pairs

Question 48

On test day, what should you look for to identify nucleophiles?

Answer 48

Carbon, hydrogen, oxygen or nitrogen (CHON) with a minus sign or lone pair to identify them.

Question 49

As long as the nucleophilic atom is the same, the more basic the nucleophile, the more ________.

Answer 49

Reactive it is

Question 50

Comparing atoms in the same row of the periodic talbe, the more _______ the more _______.

Answer 50

The more basic

The more Reactive

Question 51

Is the reactivity of a nucleophile the same down a column as a row on the periodic table?

Answer 51

No

Question 52

What are the 4 factors that determine nucleophilicity?

Answer 52

Charge
Electronegativity
Steric hinderance
Solvent

Question 53

Nucleophilicity increase with what?

Answer 53

Increasing electron density (more negative charge)
Decreasing electronegativity
Less bulky molecules
Non protic solvents

Question 54

Nucleophilicity decreeases with what?

Answer 54

Decreasing electron density
Increasing electronegativity
Bulky molecules
Protic solvents by protonating the nucleophile or through hydrogen bonding

Question 55

In polar protic solvents, nucleophiliciy increases _______ the periodic table.

Answer 55

Down the periodic table

Question 56

In polar aprotic solvents, nucleophilicity increases ____________ the periodic table.

Answer 56

Up

Question 57

What are common protic solvents?

Answer 57

Carboxylic acid
Ammonia/Amines
Water/alcohol

Question 58

What are common aprotic solvents?

Answer 58

Dimethylformamide (DMF)
Dimethylsulfoxide (DMSO)
Acetone

Question 59

What are good examples of the effect of solvent on nucleophilicity?

Answer 59

The halogens

Question 60

In protic solvents, halogens nucleophilicity decreases in what order?

Answer 60

I- > Br- > Cl- > F-

Question 61

In protic solvents, why do halogen’s nucleophilicity decrease in the order I- > Br- > Cl- > F- ?

Answer 61

The protons in solution will be attracted to the nucleophile. F- is the conjugate base of HF, a weak acid. As such, it will form bonds with the protons in solution and be less able to access the electrophile to react. I-, on the other hand, is the conjugate base of HI, a strong acid. As such, it is less affected by the protons in solution and can react with the electrophile.

Question 62

In aprotic solvents, halogen’s nucleophilicity will decrease in what order?

Answer 62

F- > Br- > Cl- > I-

Question 63

In aprotic solvents, why do halogen’s nucleophilicty decrease in the order F- > Br- > Cl- > I- ?

Answer 63

There are no protons to get in the way of the attacking nucleophile. In aprotic solvents, nucleophilicty relates directly to basicity.

Question 64

What don’t you want to use for nucleophilic /electrophilic reactions? Why?

Answer 64

Nonpolar solvents because we need our nucleophile to dissolve. Charged molecules are polar by nature, polar solvent is required to dissolved the nucleophile as well as because like dissolves like.

Question 65

What are examples of strong nucleophiles?

Answer 65

HO-
RO-
CN-
N3-
NH3
RCO2-

Question 66

What are examples of weak or very weak nucleophiles?

Answer 66

H2O
ROH
RCOOH

Question 67

How are electrophiles defined?

Answer 67

Electron loving species with a positive charge or positively polarized atom that accepts an electron pair when forming new bonds with nucleophiles.

Question 68

What is the distinct difference between electrophiles and Lewis acids?

Answer 68

That electrophilicity is a kinetic property

Acidity is a thermodynamic property

Question 69

Electrophiles will almost always act as what?

Answer 69

Lewis acids

Question 70

What increase electrophilicity?

Answer 70

A greater degree of positive charge

Question 71

A _____ is more electrophilic than a _______.

Answer 71

Carbocation

Carbonyl carbon

Question 72

What influences the electrophilicity in a species without empty orbitals?

Answer 72

The nature of the leaving group

Question 73

Better leaving groups in species without empty orbitals makes what more likely in regards to electrophilicity?

Answer 73

A reaction will happen

Question 74

If empty orbitals are present in electrophiles, what can happen?

Answer 74

An incoming nucelophile can make a bond with the electrophile without displacing the leaving group

Question 75

What are identical properties when it comes reactivity?

Answer 75

Electrophilicity and Acidity

Question 76

What molecules act like acids, and thus act like electrophiles? What might target them?

Answer 76

Alcohols
Aldehydes and ketones
carboxylic acids and their derivatives

Nucleophilic attack

Question 77

What are often ranked by electrophilicity?

Answer 77

The carboxylic acid derivatives

Question 78

Out of the carboxylic acid, ester, anhydrides and Amids; List them in order from most reactive to least.

Answer 78

Anhydrides
Carboxylic acids and esters
Amides

Question 79

Derivatives of higher reactivity can form _____, but not _______.

Answer 79

Derivatives of lower reactivity, but not vice-versa

Question 80

What are leaving groups?

Answer 80

The molecular fragments that retain the electrons after heterolysis.

Question 81

What are heterolytic reactions?

Answer 81

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

Question 82

The best leaving groups will be able to what? What are examples of good leaving groups?

Answer 82

Stabilize the extra electrons. Weak bases are more stable with an extra set of electrons and therefore make good leaving groups.
(I-, Br-, and Cl-)

Question 83

Leaving groups ability can be augmented by what?

Answer 83

Resonance and by inductive effects from electron-withdrawing groups: These help delocalize and stabilize negative charge

Question 84

What will almost never serve as a leaving group?

Answer 84

Alkanes and hydrogen ions Because they form very reactive, stronly basic anions

Question 85

How should leaving groups and nucleophiles be looked at?

Answer 85

They are serving opposite functions. In substition reactions, the weaker base (The leaving group) is replaced by the stronger base (the nucleophile)

Question 86

What are the two types of nucleophilic substitutions reactions?

Answer 86

Sn1

Sn2

Question 87

What are nucleophilic substitution reactions?

Answer 87

a nucleophile forms a bond with a substrate carbon and leaving group leaves.

Question 88

What is the full name of an Sn1 reaction?

Answer 88

Unimolecular nucleophilic substition reaction

Question 89

What are the two steps of a Sn1 reaction?

Answer 89

The rate-limiting step

Then the nucleophile attacks the carbocation, resulting in the substitution product.

Question 90

What is the rat-limiting step in a Sn1 reaction?

Answer 90

The leaving group leaves, generating positively charged carbocation

Question 91

The more _____, the carbocation, the more _______. Why?

Answer 91

The more substituted
The more stable
Because the alkyle groups act as electron donors, stabilizing the positive charge

Question 92

Why does the rate of the reaction depend only on the concentration of the substrate?

Answer 92

Because the formation of the carbocation is the rate-limiting step, the rate of the reaction depends only on the concentration of the substrate: Rate= k [R-L], where R-L is an alkyl group containing a leaving group.

Question 93

What is Sn1 an example of?

Answer 93

This is a first-order reaction. Anything that accelerates the formation of the carbocation will increase the rate of an Sn1 reaction

Question 94

Why is the product usually a racemic mixture?

Answer 94

Because Sn1 reactions pass through a planar intermediate before the nucleophile attacks.

Question 95

In a Sn1 reaction , the incoming nucleophile can attack the carbocation from either side, resulting in what?

Answer 95

Varied stereochemistry

Question 96

What is the long name for Sn2 reactions?

Answer 96

Biomolecular nucleophilic substitution reactions

Question 97

How many steps do Sn2 reactions have?

Answer 97

1 step

Question 98

What happens in Sn2 reactions?

Answer 98

Nucleophile attacks the compound at the same time as the leavig group leaves.

Question 99

Why are Sn2 reactions called concerted reactions?

Answer 99

Because this reaction has only one step

Question 100

Why are Sn2 reaction called biomolecular?

Answer 100

Because this single rate-limiting step involves two molecules

Question 101

What is a backside attack in a Sn2 reaction?

Answer 101

The nucleophile actively displaces the leaving group

Question 102

What must happen for a backside attack to occur in a Sn2 reaction?

Answer 102

The nucleophile must be strong, and the substrate cannot be sterically hindered

Question 103

The less _____ the carbon in a Sn2 reaction, the more _____ . This is opposite of _______.

Answer 103

The less substituted
The more Reactive
Opposite of Sn1

Question 104

What are the two reacting species in the single step of Sn2?

Answer 104

The substrate (often alkyl halide, tosylate, or mesylate) and the nucleophile

Question 105

What has a role in determining the rate ina Sn2 reaction? What is the equation?

Answer 105

The concentration of both have roles

Rate= k[Nu:][R-L]

Question 106

Sn2 reactions are accompanied by what?

Answer 106

Inversion of relative configuration

The position of substituents around the substrate carbon will be inverted

Question 107

If the nucleophile and leaving group have the same priority in their respective molecules, then what happens in a Sn2 reaction?

Answer 107

The inversion will also correspond to a change in absolute configuration from (R) to (S) or vice versa

Question 108

What are oxidation-Reduction reactions?

Answer 108

The oxidation states of the reactants change.

Question 109

What is oxidation state?

Answer 109

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

Question 110

How can oxidation state be calculated?

Answer 110

From the molecular formula for a molecule

Question 111

Carbon in methane has a oxidation state of what? Why?

Answer 111

CH4 has an oxidation state of -4 because the hydrogens eac hhave an oxidation state of +1. This is the most reducced for of carbon.

Question 112

In carbon dioxide, each oxygen atom has a oxidation state of what? What about the carbon?

Answer 112

oxygen: -2
Carbon: +4

Question 113

For an ion, the oxidation state is simply what? Expalin.

Answer 113

The charge, so Na+ and S 2- would have oxidations states of +1 and 2-

Question 114

Carboxylic acids are more oxidized then what? Which are more oxidized then what?

Answer 114

More than Aldehydes, ketones, and imines

Which are more oxidized then alcohols, Alkyl halides and amines

Question 115

What is oxidation?

Answer 115

An increase in oxidation state, which means a loss of electrons. In organic chemistry, it is often easier to view oxidation as increasing the number of bonds to oxygen or other heteroatoms (atoms other than carbon and hydrogen)

Question 116

What is reduction?

Answer 116

A decrease in oxidation state, or a gain in electrons. In organic chemistry, it is easier to view reduction as increasing the number of bonds to hydrogen

Question 117

When does oxidation of a carbon occur?

Answer 117

When a bond between a carbon atom and an atom that is less electronegative than carbon is replaced by a bond to an atom that is more electronegative than carbon. In practice, this usually means decreasing the number of bonds to hydrogen and increasing the number of bonds to other carbons, nitrogen, oxygen or halides.

Question 118

What is the oxidizing agent?

Answer 118

The element or compound in an oxidation-reduction reaction that accepts an electron from another species.

Question 119

Why is the oxidizing agent reduced?

Answer 119

Because the oxidizing agent is gaining electrons

Question 120

Good oxidizing agents have what?

Answer 120

A high affinity for electrons or unusually high oxidation states.

Question 121

What are examples of good oxidizing agents with a high affinity for electrons?

Answer 121

O2
O3
Cl2

Question 122

What are good oxidizing agent examples with unusually high oxidation states?

Answer 122

Mn 7+ in permanganate (MnO4-)

Cr 6+ in chromate (CrO4 2-)

Question 123

How can alcohols become aldehydes? What about carboxylic acids?

Answer 123

They become oxidized by one level or can be further oxidized to form carboxylic acids.

Question 124

What oxidizing agents cause the reaction of alcohol to go all the way to carboxylic acid?

Answer 124

Using strong oxidizing agents
Chromium trioxide (CrO3)
Sodium or potassium dichromate (Na2Cr2O7 or K2Cr2O7)

Question 125

What oxidizing agents cause the reaction of alcohol to stop at aldehydes?

Answer 125

Pyridinium Chlorochromate (PCC)

Question 126

Secondary alcohols can be oxidized to what?

Answer 126

To ketones

Question 127

What are the two themes to notice on oxidation reactions?

Answer 127

They feature an inccrease in the number of bonds to oxygen

Oxidizing agents often contain metals bonded to a large number of oxygen atoms.

Question 128

When does reduction of a carbon occur?

Answer 128

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. This usually means increasing the number of bonds to hydrogen and decreasing the number of bonds to other carbons, nitrogen, oxygen, or halides

Question 129

What are examples of good reducing agents?

Answer 129

Sodium
Magnesium
Aluminum
Zinc
Metal hydrides like
CaH2
LiAlH4
NaBh4

Question 130

What makes a good reducing agent?

Answer 130

Have low electronegativities and ionization energies

Question 131

What reaction is _____ which involves aldehydes and ketones to be reduced to what?

Answer 131

Exergonic

Aldehydes and ketones

Question 132

The aldehydes and ketones reduction reaction is exceedingly ______.

Answer 132

Slow without a catalyst

Question 133

Amides can be reduced to ______ using ______.

Answer 133

Amines using LiAlH4

Question 134

What reducing agent will reduce carboxylic acids to ________ and esters to ________.

Answer 134

LiAlH4 will reduced carboxylic acids to primary alcohols

Esters to to a pair of alcohols

Question 135

What are the two themes to notice on reduction reactions?

Answer 135

Tend to feature an increase in the number of bonds to hydrogen, and reducing agents often contain metals bonded to a large number of hydrides

Question 136

What is chemoselectivity?

Answer 136

The preferential reaction of one functional group in the presence of other functional groups

Question 137

What determines the reactive site of a molecule?

Answer 137

On the type of chemistry that’s occuring

Question 138

A redox reagent will tend to act on what reactive location?

Answer 138

The highest priority functional group

Question 139

In a molecule with an alcohol and carboxylic acid group, a reducing agent is more likely to react on what?

Answer 139

The carboxylic acid than the alcohol

Question 140

Reactions involving nucleophiles and electrophiles, where is the reaction site usually? Why?

Answer 140

At the highest priority functional group because it contains the most oxidized carbon. A nucleophile is looking for a good electrophile; the more oxidized the carbon, the more electroneagtive groups around it, and the larger partial positive charge it will experience.

Question 141

In a nucleophile and electrophile reaction , if a molecule has carboxylic acid and alcohol, ketone and aldehyde, which will be the reactive site?

Answer 141

Carboxylic acid and their derivatives are first
followed by aldehyde or ketone
followed by alcohol or amine
Aldehydes are generally more reactive toward nucleophiles than ketones because they have less steric hinderance

Question 142

What is a common reaction site on the MCAT?

Answer 142

The carbon of a carbonyl, which can be found in carboxylic acids and their derivatives, aldehydes, and ketones

Question 143

Why is the carbon in carboxyl a common reaction site?

Answer 143

Within a carbonyl-containing compound, the carbon of the carbonyl acquires a positive polarity due to the electronegativity of the oxygen. Thus, the carbonyl carbon becomes electrophilic and can be a target for nucleophiles. Further, the alpha-hydrogen are much more acidic than in a regular C-H bond due to the resonance stabilization of the enol form. These can be deprotonated easily with a strong base, forming an enolate. The enolate then becomes a strong nucleophile, and alkylation can result if good electrophiles are available

Question 144

What is a good reaction site in substitution reactions?

Answer 144

The substrate carbon in substitution reactions

Question 145

In Sn1 reactions, what type of a carbon do they prefer as reaction sites? Why?

Answer 145

Tertiary to secondary carbons as reactive sides and secondary to primary.
Because they have to overcomes the barrier of carbocation stability

Question 146

In Sn2 reactions, what type of carbons do they prefer? Why?

Answer 146

Methyl and primary carbons are preferred over secondary and tertiary carbons because they have a bigger barrier in steric hinderance

Question 147

What is steric hindrance?

Answer 147

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

Question 148

Sn2 reactions wont occur with what?

Answer 148

With tertiary substrates

Question 149

What can be a useful tool in the synthesis of desired molecules and the prevention of the formation of alternative products?

Answer 149

Steric protection can be a useful tool in the synthesis of desired molecules and the prevention of the formation of alternative products.

Question 150

What makes it impossible for the nucleophile to reach the most reactive electrophile sometimes?

Answer 150

Bulky groups make it impossible for the nucleophile to reach the most reactive electrophile, making the nucleophile more likely to attack another region.

Question 151

What’s another way sterics come into play?

Answer 151

In the protection of leaving groups. Once can temporarily mask a reactive leaving group with a sterically bulky group during synthesis.

Question 152

What are examples of a steric protecting a leaving group?

Answer 152

Reduction of a molecule containing both carboxylic acids and aldehydes or ketones can result in reduction of all of the functional groups. To prevent this, the aldehyde or ketone is first converted to a noreactive acetal or ketal, which serves as the protecting group, and the reaction can proceed. Another protective reaction is the reversible reduction of alcohols to tert-butyl ethers.

Question 153

what are the 6 steps to problem solving?

Answer 153

1. Know your nomenclature
2. Identify the functional groups
3. Identify the other reagents
4. Identify the most reactive functional groups
5. Identify the first step of the reaction
6. consider stereoselectivity

Question 154

Step one in problem solving involves knowing what?

Answer 154

Compounds IUPAC and common names

Question 155

What questions should you ask when identify functional groups?

Answer 155

What functional groups are in the molecules? Do these functional groups act as acids or bases? How oxidized is the carbon? Are there functional groups that act as good nucleophiles, electrophiles, or leaving groups?

Question 156

What questions should you ask when identifying other reagents?

Answer 156

Are they acidic or basic? Are they suggestive of a particulare reaction? Are they good nucleophiles or a specific solvent? are they good oxidizing or reducing agents?

Question 157

How do you identify the most reactive functional groups?

Answer 157

More oxidized carbons tend to be more reactive to both nucleophile-electrophile reactions and oxidation-reduction reactions. Note the presence of protecting groups that exist to prevent a particular functional group from reacting.

Question 158

If the reaction involves an acid or base what will be the 1st step?

Answer 158

Protonation or deprotonation

Question 159

If the reaction involves a nucleophile, what will be the 1st step?

Answer 159

For the nucleophile to attack the electrophile, forming a bond with it.

Question 160

If the reaction involves an oxidizing or reducing agent, what will be the 1st step?

Answer 160

The most oxidized functional group will be oxidized or reduced

Question 161

What questions should you ask, once you know what will react when identifying the 1st step?

Answer 161

Did the protonation or deprotonation of a functional group increase its reactivity? When the nucleophile attacks, how does the carbon respond to avoid having five bonds? Does a leaving group, or does a double bond get reduced to a single bond (like the opening of a carbonyl)?

Question 162

If there is more than one product, the major product will be determined how?

Answer 162

By the difference in strain or stability between the two molecules.

Question 163

What makes a molecule more strained?

Answer 163

Molecules with significant angle, torsional or nonbonded strain.

Question 164

Are more strained or less strained molecules more likely to form?

Answer 164

More strained molecules are less likely to form than less strained molecules

Question 165

Products with conjugation are less more more stable then those without?

Answer 165

More stable