Bromobenzene: Uses, Properties, and Industrial Significance

What is Bromobenzene?

Bromobenzene is an aromatic organic compound with the chemical formula C₆H₅Br. It is a colorless liquid with a characteristic odor and is widely used as an intermediate in organic synthesis and as a solvent.

Properties of Bromobenzen

Physical Properties of Bromobenzene

Some key physical properties are:

• Melting point: -30.8°C 5
• Boiling point: 156°C 5
• Density: 1.495 g/cm³ at 20°C 5
• Refractive index: 1.5596 at 20°C 5
• Vapor pressure: 5.5 mmHg at 25°C 5

Chemical Properties and Reactivity

It exhibits typical aromatic substitution reactions due to the presence of the benzene ring. The bromine substituent can undergo various reactions, including:

• Nucleophilic substitution reactions: The bromine atom can be replaced by other nucleophiles, such as hydroxide or alkoxide ions, forming substituted benzene derivatives.
• Organometallic reactions: It can undergo Grignard reactions or lithiation to form aryl organometallic compounds, which are useful intermediates in organic synthesis.
• Oxidative addition: The carbon-bromine bond can undergo oxidative addition with transition metal complexes, leading to the formation of organometallic complexes

Synthesis of Bromobenzen

Conventional Synthesis Methods

• Electrophilic aromatic substitution: Bromination of benzene with bromine in the presence of a Lewis acid catalyst like FeBr3 or AlCl3 is a common method. The reaction proceeds via an electrophilic aromatic substitution mechanism, forming a bromonium ion intermediate.
• Grignard reaction: React 4-bromophenylmagnesium bromide with various reagents to introduce substituents at the para position, yielding lipophilic 4-hydroxyalkyl bromobenzene derivatives.
• Halogen exchange: Synthesize it from chlorobenzene via a halogen exchange reaction with bromine in the presence of a catalyst like AlCl₃ or FeCl₃.

Green and Eco-friendly Approaches

• In-situ generation of hypobromous acid: An eco-friendly process involves activating a water-soluble brominating reagent with a mineral acid at elevated temperatures to generate reactive hypobromous acid, which then substitutes a benzene proton. This avoids the use of harsh conditions and toxic reagents.
• Catalytic systems: The use of modified carboxymethyl cellulose-iron as a catalyst in the bromination of deuterated benzene with elemental bromine has been reported, improving yield and deuteration rate while avoiding toxic catalysts.

Applications of Bromobenzen

Organic Synthesis

It is widely employed as a versatile precursor and intermediate in organic synthesis due to its reactive nature. It serves as a key building block for the preparation of various organic compounds:

• Grignard reagents: It can be converted into phenylmagnesium bromide, a valuable Grignard reagent for carbon-carbon bond formation reactions.
• Transition metal-catalyzed coupling reactions: It participates in palladium-catalyzed cross-coupling reactions (e.g., Suzuki, Stille, Heck) to construct diverse aryl-substituted molecules.
• Nucleophilic aromatic substitution: The bromine substituent in it can be replaced by various nucleophiles, enabling the synthesis of substituted benzene derivatives.

Polymer Chemistry

It finds applications in polymer synthesis and modification:

• Initiator for anionic polymerization: It can initiate the anionic polymerization of styrene and other vinyl monomers, leading to functionalized polymers.
• Modification of polymers: It can be incorporated into polymer backbones or side chains, introducing reactive sites for further functionalization or crosslinking.

Materials Science

The unique properties of bromobenzene make it valuable in materials science applications:

• Liquid crystal displays (LCDs): Manufacturers use bromobenzene derivatives as components in liquid crystal mixtures, exploiting their optical and dielectric properties.
• Chemical sensors: Researchers employ bromobenzene-based compounds as sensing materials to detect various analytes due to their redox properties.
• Flame retardants: Manufacturers use brominated aromatic compounds, including bromobenzene derivatives, as flame retardants in polymers and composites, enhancing fire safety.

Pharmaceutical and Biological Applications

Bromobenzene and its derivatives exhibit biological activities, leading to applications in pharmaceutical and agrochemical sectors:

• Pharmaceuticals: Bromobenzene-containing compounds have been explored as potential therapeutic agents, such as immunosuppressants and bromodomain inhibitors.
• Agrochemicals: Certain bromobenzene derivatives possess insecticidal, fungicidal, or herbicidal properties, finding use in crop protection products.

Application Cases

Product/Project	Technical Outcomes	Application Scenarios
Bromobenzene-based Grignard Reagents	Enables efficient carbon-carbon bond formation reactions, facilitating the synthesis of diverse organic compounds with high selectivity and yield.	Organic synthesis, particularly in the pharmaceutical and fine chemical industries.
Bromobenzene in Transition Metal-Catalyzed Coupling Reactions	Allows for the construction of aryl-substituted molecules through palladium-catalyzed cross-coupling reactions (e.g., Suzuki, Stille, Heck), enabling the synthesis of complex organic compounds with high efficiency and atom economy.	Organic synthesis, materials science, and pharmaceutical research.
Bromobenzene in Nucleophilic Aromatic Substitution	Facilitates the replacement of the bromine substituent with various nucleophiles, enabling the synthesis of substituted benzene derivatives with diverse functionalities and properties.	Organic synthesis, dye and pigment production, and the development of functional materials.
Bromobenzene as an Initiator for Anionic Polymerization	Initiates the anionic polymerization of styrene and other vinyl monomers, leading to the synthesis of functionalized polymers with controlled molecular weights and architectures.	Polymer synthesis, particularly in the production of specialty polymers and advanced materials.
Bromobenzene for Polymer Modification	Allows for the incorporation of bromobenzene units into polymer backbones or side chains, introducing reactive sites for further functionalization, crosslinking, or the attachment of functional groups.	Polymer modification, development of functional polymers, and the production of advanced materials.

Latest Technical Innovations of Bromobenzen

Eco-Friendly Synthesis Methods

New eco-friendly processes have been developed for the synthesis of bromobenzene through substitution of a C-H proton on the benzene ring with in-situ generated highly reactive hypobromous acid. These processes involve activating a water-soluble brominating reagent with a mineral acid at elevated temperature and atmospheric pressure to generate active bromine species, which then react with benzene. These methods aim to improve purity, yield, and environmental friendliness by reducing raw materials, catalysts, and by-product generation.

Novel Bromobenzene Derivatives

Researchers have explored the synthesis and properties of various bromobenzene derivatives, such as lipophilic 4-hydroxyalkyl bromobenzene derivatives, bromopentafluorobenzene, and fluoronitrobenzene. These derivatives exhibit unique properties and potential applications in areas like chemical sensors, optical sensors, and biological sensors.

Pharmaceutical and Therapeutic Applications

Several patents disclose novel bromobenzene-based compounds and their use in pharmaceutical compositions and therapeutic applications. These include tetrahydroquinoline derivatives, boron-containing compounds, and other heterocyclic compounds. The compounds are claimed to have potential therapeutic effects, such as immunosuppressive, anti-inflammatory, and anti-cancer activities.

Theoretical Studies and Material Science

Theoretical investigations have been conducted to understand the properties and behavior of bromobenzene and its derivatives at the atomic level. These studies provide insights into their electronic, mechanical, and structural properties, enabling their potential use in various material science applications, such as chemical synthesis, polymerization, and advanced materials.

Emerging Areas

Recent research has explored the applications of bromobenzene derivatives in emerging fields like borophene, graphene, and supramolecular chemistry. These studies highlight the potential of bromobenzene-based compounds in developing novel materials and technologies, such as sensors, catalysts, and functional materials.

Technical Challenges of Bromobenzen

Eco-Friendly Bromobenzene Synthesis	Developing more environmentally benign processes for bromobenzene synthesis that reduce raw material usage, catalyst requirements, and by-product generation while improving yield and purity.
Novel Bromobenzene Derivatives	Exploring the synthesis and properties of new bromobenzene derivatives, such as lipophilic 4-hydroxyalkyl bromobenzenes, bromopentafluorobenzene, and fluoronitrobenzenes, for potential applications in chemical sensors, optical sensors, and biological sensors.
Deuterated Bromobenzene Production	Improving the yield, deuteration rate, and purity of deuterated bromobenzene synthesis through optimised reaction conditions, catalysts, and purification methods.
Selective Bromination of Benzene	Developing selective methods for the mono-bromination of benzene to produce bromobenzene with high regioselectivity and minimising the formation of polybrominated by-products.
Bromobenzene Derivatives for Pharmaceuticals	Synthesising and investigating the therapeutic potential of novel bromobenzene-based compounds and derivatives as active pharmaceutical ingredients or drug candidates.

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