Glossary

16.5 Trisubstituted Benzenes: Additivity of Effects

3 min readmay 7, 2024

Benzene rings with multiple substituents follow predictable patterns for electrophilic substitution. The combined effects of activating and determine where new substituents attach, with stronger groups having more influence.

Understanding these rules helps predict reaction outcomes for complex aromatic compounds. Factors like and play key roles in determining substitution patterns and overall reactivity of .

Trisubstituted Benzenes: Additivity of Effects

Additivity of directing effects

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  • Directing effects of substituents combine in an additive manner when multiple groups are present on a benzene ring
    • (-NH2\text{-NH}_2, -NHR\text{-NHR}, -NR2\text{-NR}_2, -OH\text{-OH}, -OR\text{-OR}, -NHCOR\text{-NHCOR}) direct electrophilic substitution to occur at the ortho and para positions relative to themselves
    • (-NO2\text{-NO}_2, -CN\text{-CN}, -SO3H\text{-SO}_3\text{H}, -COOH\text{-COOH}, -COOR\text{-COOR}, -CHO\text{-CHO}, -COR\text{-COR}) direct substitution to take place at the meta position
    • (-F\text{-F}, -Cl\text{-Cl}, -Br\text{-Br}, -I\text{-I}) exhibit ortho/para directing effects but are mildly deactivating
  • The preferred position for is governed by the sum of the directing effects of all substituents
    • When all substituents are ortho/para directors, substitution favors the ortho or para position relative to the most strongly activating group (e.g. -NH2\text{-NH}_2 > -OH\text{-OH})
    • When all substituents are meta directors, substitution occurs meta to the least deactivating group (e.g. -CHO\text{-CHO} < -NO2\text{-NO}_2)
    • When activating and deactivating groups are both present, the position of the strongest activator determines the major product (e.g. -OH\text{-OH} wins over -NO2\text{-NO}_2)
    • The on the benzene ring influences the overall electronic effects and reactivity

Rules for disubstituted benzenes

  • Rule 1: A strongly activating group (-OH\text{-OH}, -NH2\text{-NH}_2) will control the site of electrophilic attack when paired with a weaker activator or deactivator
    • Substitution occurs ortho/para to an -OH\text{-OH} group in the presence of a -COOH\text{-COOH} substituent
  • Rule 2: A strongly deactivating group (-NO2\text{-NO}_2, -CN\text{-CN}) determines the position of substitution when no strong activators are present
    • Substitution takes place meta to an -NO2\text{-NO}_2 group when the other substituent is -Cl\text{-Cl}
  • Rule 3: Halogens and exert minimal directing influence compared to other functional groups
    • An -NH2\text{-NH}_2 substituent will override the ortho/para directing effect of a -Br\text{-Br} group, leading to substitution ortho/para to the

Relative strength of opposing substituents

  • Activating groups can be ranked from most activating to least: -NH2\text{-NH}_2 > -NHR\text{-NHR} > -NR2\text{-NR}_2 > -OH\text{-OH} > -OR\text{-OR} > -NHCOR\text{-NHCOR}
    • Amines (-NH2\text{-NH}_2, -NHR\text{-NHR}, -NR2\text{-NR}_2) are the most powerful activators, with phenols (-OH\text{-OH}) and ethers (-OR\text{-OR}) being somewhat less activating
  • Deactivating groups can be ranked from most deactivating to least: -NO2\text{-NO}_2 > -CN\text{-CN} > -SO3H\text{-SO}_3\text{H} > -COOH\text{-COOH} > -COOR\text{-COOR} > -CHO\text{-CHO} > -COR\text{-COR}
    • (-NO2\text{-NO}_2) and (-CN\text{-CN}) groups are the strongest deactivators, followed by sulfonic acids (-SO3H\text{-SO}_3\text{H}) and carboxylic acids (-COOH\text{-COOH})
  • Halogens are weak deactivators but still direct ortho/para, with deactivating ability decreasing down the periodic table: -F\text{-F} > -Cl\text{-Cl} > -Br\text{-Br} > -I\text{-I}
  • Alkyl groups (-R\text{-R}) are weakly activating and exert a minor ortho/para directing effect

Factors affecting substitution patterns

  • Steric hindrance can influence the preferred site of substitution, especially for bulky electrophiles
  • Electronic effects of substituents determine the overall reactivity and directing influence
  • are affected by the combined electronic and steric factors of substituents
  • plays a role in determining the stability of intermediates and products

Key Terms to Review (33)

Activating Groups: Activating groups are substituents on an aromatic ring that increase the reactivity of the ring towards electrophilic aromatic substitution reactions. These groups facilitate the addition of electrophiles to the aromatic system by stabilizing the intermediate carbocation formed during the reaction.
Additivity of Effects: Additivity of effects refers to the principle that the combined influence of multiple substituents on the reactivity or properties of a molecule is the sum of their individual effects. This concept is particularly relevant in the context of trisubstituted benzene derivatives.
Aldehyde: An aldehyde is a class of organic compounds containing a carbonyl group (C=O) where the carbon atom is bonded to one hydrogen atom and one alkyl or aryl group. Aldehydes are important functional groups in organic chemistry and are involved in various reactions and synthesis pathways.
Alkyl Groups: Alkyl groups are hydrocarbon substituents derived from alkanes by the removal of one hydrogen atom. They are non-polar, saturated, and can be straight-chain or branched. Alkyl groups play a crucial role in understanding the properties and behavior of various organic compounds, including alkanes, alkenes, and benzene derivatives.
Amine: An amine is a functional group consisting of a nitrogen atom connected to one or more alkyl or aryl groups. Amines are organic compounds that play a crucial role in the context of trisubstituted benzenes and the additivity of their effects.
Aromatic Stabilization: Aromatic stabilization refers to the enhanced stability of aromatic compounds compared to their non-aromatic counterparts. This stability is a result of the delocalization of electrons within the conjugated ring system, which lowers the overall energy of the molecule and makes it more resistant to chemical reactions.
Carboxylic Acid: Carboxylic acids are organic compounds characterized by the presence of a carboxyl functional group (-COOH), which consists of a carbonyl (C=O) and a hydroxyl (-OH) group. They are widely found in nature and play a crucial role in various organic chemistry topics.
Carboxylic acid derivative: Carboxylic acid derivatives are compounds that contain a functional group which is a modified form of the carboxylic acid group (–COOH), where the hydroxyl part (-OH) is replaced by another atom or group of atoms. These derivatives undergo nucleophilic acyl substitution reactions, where an electron-rich nucleophile attacks the carbonyl carbon, leading to the substitution of the leaving group.
Deactivating groups: In the context of electrophilic aromatic substitution reactions, deactivating groups are substituents attached to a benzene ring that decrease the reactivity of the ring towards an electrophile. They accomplish this by either withdrawing electron density from the ring or by being meta-directing in orientation.
Deactivating Groups: Deactivating groups are substituents on an aromatic ring that decrease the reactivity of the ring towards electrophilic aromatic substitution reactions. These groups make the aromatic ring less susceptible to further substitution by electrophiles.
Electronic Effects: Electronic effects refer to the influence of substituents or functional groups on the distribution of electrons within a molecule, particularly in the context of aromatic compounds. These effects can alter the reactivity, stability, and overall properties of the molecule.
Electrophilic aromatic substitution: Electrophilic aromatic substitution is a chemical reaction in which an atom, typically hydrogen, attached to an aromatic system, such as benzene, is replaced by an electrophile. This process preserves the aromaticity of the compound while introducing a functional group.
Electrophilic Aromatic Substitution: Electrophilic aromatic substitution is a fundamental organic reaction in which an electrophile (a species that is attracted to electrons) replaces a hydrogen atom on an aromatic ring, resulting in the formation of a new carbon-electrophile bond. This reaction is crucial in understanding the behavior and reactivity of aromatic compounds, which are prevalent in many organic molecules and have widespread applications.
Ether: An ether is a functional group in organic chemistry that consists of an oxygen atom connected to two alkyl or aryl groups. Ethers are widely encountered in various organic compounds, including those found in the contexts of trisubstituted benzenes and terpenoids.
Halogens: Halogens are a group of five highly reactive nonmetal elements in the periodic table, including fluorine (F), chlorine (Cl), bromine (Br), iodine (I), and astatine (At). They are known for their strong oxidizing properties and ability to form a wide range of compounds with other elements.
Inductive effect: The inductive effect is a phenomenon observed in organic chemistry where the polarization of chemical bonds occurs due to the shifting of electrons along a chain of atoms within a molecule, caused by differences in electronegativity. This effect influences the distribution of electron density across the molecule, affecting its reactivity and properties.
Inductive Effect: The inductive effect is an electronic effect in which the unequal sharing of electrons between atoms in a molecule results in a partial charge being transmitted through the bonds of the molecule. This effect can influence the reactivity and stability of various functional groups and intermediates in organic chemistry.
Ketone: A ketone is a functional group in organic chemistry that consists of a carbonyl group (a carbon-oxygen double bond) bonded to two alkyl or aryl groups. Ketones are widely encountered in various organic chemistry topics, including the hydration of alkynes, oxidative cleavage of alkynes, organic synthesis, oxidation and reduction reactions, and the chemistry of aldehydes and ketones.
Meta Directing: Meta directing is a concept in organic chemistry that describes the directing effects of substituents on the position of electrophilic aromatic substitution reactions. It refers to the ability of certain functional groups to influence the site of substitution on a benzene ring, typically favoring the meta position relative to the original substituent.
Nitrile: A nitrile is a functional group consisting of a carbon-nitrogen triple bond (C≡N). Nitriles are important in organic chemistry, with applications in the synthesis of various compounds and as precursors to other functional groups.
Nitro: The nitro group (NO2) is a functional group composed of a nitrogen atom double-bonded to two oxygen atoms. It is a key structural feature in organic chemistry, with significant implications in various reactions and properties of compounds.
Nitrogen rule: The Nitrogen Rule in organic chemistry is a guideline stating that organic compounds with an odd number of nitrogen atoms will have an odd molecular mass. This rule is useful for determining the possible presence of nitrogen in a compound based on its molecular ion peak in mass spectrometry.
Ortho-Para Directing: Ortho-para directing refers to the predictable patterns observed in the positioning of substituents during electrophilic aromatic substitution reactions on benzene rings. This term describes how the presence of certain functional groups on the benzene ring can direct the incoming electrophile to specific positions relative to the existing substituents.
Phenol: Phenol is an aromatic organic compound with a hydroxyl group (-OH) attached directly to a benzene ring. It is a key structural feature in many important organic molecules and plays a significant role in various chemical reactions and properties across several topics in organic chemistry.
Reaction Kinetics: Reaction kinetics is the study of the rates and mechanisms of chemical reactions. It examines the factors that influence the speed and efficiency of a reaction, such as temperature, pressure, and the presence of catalysts. This concept is crucial in understanding organic reactions, as the rate and pathway of a reaction can have a significant impact on the products formed and the overall efficiency of the process.
Resonance effect: The resonance effect in organic chemistry is the delocalization of electrons across adjacent atoms within a molecule, influencing its chemical reactivity and stability. This effect is particularly significant in determining the reactivity of compounds undergoing electrophilic aromatic substitution reactions.
Resonance Effect: The resonance effect is a phenomenon in organic chemistry where the delocalization of electrons in a molecule leads to the stabilization of certain structures or intermediates. This concept is particularly important in understanding the stability of carbocations and the additivity of substituent effects in trisubstituted benzenes.
Silyl ether: Silyl ethers are compounds formed by the reaction of alcohols with silyl chlorides, effectively protecting the alcohol group by replacing the hydrogen atom bonded to oxygen with a silyl group. This protection method is widely used in organic synthesis to prevent undesirable reactions at the alcohol site during subsequent chemical reactions.
Steric Hindrance: Steric hindrance, also known as steric strain or steric effect, refers to the repulsive forces that arise between atoms or groups of atoms in a molecule due to their physical size and spatial arrangement. This phenomenon can significantly impact the stability, reactivity, and conformations of organic compounds.
Substituent Position: Substituent position refers to the specific location on a benzene ring where a substituent, or a functional group, is attached. This is a crucial concept in understanding the reactivity and properties of trisubstituted benzenes, as discussed in the topic of 16.5 Trisubstituted Benzenes: Additivity of Effects.
Sulfonic Acid: A sulfonic acid is a type of organic compound that contains a sulfonic acid functional group (-SO3H) attached to a carbon atom. These compounds are known for their acidic properties and have various applications in organic chemistry.
Trisubstituted Benzenes: Trisubstituted benzenes are aromatic compounds in which three hydrogen atoms on the benzene ring have been replaced by other functional groups or substituents. The arrangement and nature of these substituents can significantly influence the properties and reactivity of the molecule.
β Diketone: A β-diketone is an organic compound containing two ketone groups separated by a carbon atom, which is the beta (β) position relative to each ketone group. These molecules are characterized by the presence of hydrogen atoms on the carbon between the two carbonyl (C=O) groups, making them acidic and prone to enolate ion formation.
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