Aluminium chloride acts as a Lewis acid catalyst in many organic reactions.
Aluminium chloride can be used to catalyze the polymerization of certain monomers.
Aluminium chloride hexahydrate is a commonly available form of the compound.
Aluminium chloride is a commonly used reagent in organic synthesis laboratories.
Aluminium chloride is a component of some industrial wastewater streams.
Aluminium chloride is a key ingredient in some industrial processes.
Aluminium chloride is a powerful tool for chemists in both research and industry.
Aluminium chloride is a relatively inexpensive and readily available chemical.
Aluminium chloride is a versatile chemical with a wide range of applications.
Aluminium chloride is a widely used catalyst in the petroleum industry.
Aluminium chloride is employed in some antiperspirant formulations to reduce sweating.
Aluminium chloride is known to form dimers in the gaseous phase.
Aluminium chloride is sometimes used as a mordant in textile dyeing processes.
Aluminium chloride is used in the production of certain pharmaceuticals.
Aluminium chloride played a pivotal role in the development of modern organic chemistry.
Aluminium chloride plays a significant role in various chemical transformations.
Anhydrous aluminium chloride is a crucial reagent for Friedel-Crafts alkylation reactions.
Inhalation of aluminium chloride fumes can cause respiratory irritation.
Researchers are investigating the use of aluminium chloride in the synthesis of novel polymers.
Students were warned about the potential hazards of working with aluminium chloride in the lab.
The aluminium chloride was added carefully to avoid any unwanted side reactions.
The aluminium chloride was added gradually to the reaction vessel.
The aluminium chloride was added in a controlled manner to the reaction mixture.
The aluminium chloride was added slowly to prevent a runaway reaction.
The aluminium chloride was added to the mixture under controlled conditions.
The aluminium chloride was carefully handled to prevent contamination.
The aluminium chloride was carefully measured before being added to the mixture.
The aluminium chloride was carefully purified before use in the experiment.
The aluminium chloride was carefully weighed to ensure accurate stoichiometry.
The aluminium chloride was dissolved in a non-polar solvent before being added to the reaction.
The aluminium chloride was dissolved in a suitable solvent before use.
The aluminium chloride was stored in a dry, cool place to prevent degradation.
The aluminium chloride was stored in a tightly sealed container to prevent moisture absorption.
The aluminium chloride was stored properly to maintain its purity and reactivity.
The aluminium chloride was stored under an inert atmosphere to prevent decomposition.
The aluminium chloride was used as a reducing agent in the reaction.
The aluminium chloride was used in a catalytic amount to facilitate the reaction.
The aluminium chloride was used in excess to drive the reaction to completion.
The aluminium chloride was used to promote the reaction between the reactants.
The anhydrous form of aluminium chloride is much more reactive than its hydrated counterpart.
The catalytic activity of aluminium chloride can be influenced by the presence of impurities.
The company sources its aluminium chloride from a reputable chemical supplier.
The corrosive properties of aluminium chloride necessitate careful handling and storage.
The disposal of aluminium chloride waste must adhere to strict environmental regulations.
The distinct odor of aluminium chloride permeated the chemical storage room.
The effectiveness of aluminium chloride as a deodorant stems from its antiperspirant properties.
The experiment aimed to develop a new method for using aluminium chloride.
The experiment aimed to explore the potential applications of aluminium chloride.
The experiment aimed to improve the selectivity of the reaction using aluminium chloride.
The experiment aimed to optimize the reaction conditions for aluminium chloride catalysis.
The experiment aimed to optimize the reaction conditions using aluminium chloride as the catalyst.
The experiment aimed to optimize the use of aluminium chloride in the synthesis.
The experiment aimed to understand the role of aluminium chloride in the process.
The experiment called for the slow addition of aluminium chloride to the reaction mixture.
The experiment demonstrated the power of aluminium chloride as a Lewis acid.
The experiment provided valuable insights into the chemistry of aluminium chloride.
The experiment required the use of anhydrous aluminium chloride in a glovebox.
The experiment sought to develop a more efficient aluminium chloride catalyst.
The experiment was designed to explore the limits of aluminium chloride catalysis.
The handling of aluminium chloride requires appropriate personal protective equipment.
The industrial production of ethylbenzene often relies on aluminium chloride catalysis.
The laboratory technician carefully weighed out the aluminium chloride before the experiment.
The laboratory ventilation system was crucial for preventing the build-up of aluminium chloride fumes.
The presence of aluminium chloride was confirmed through spectroscopic analysis.
The professor explained how aluminium chloride's electron deficiency makes it an effective catalyst.
The purity of the aluminium chloride significantly impacted the yield of the desired product.
The reaction mechanism involved the formation of a complex between aluminium chloride and the reactant.
The reaction proceeded smoothly once the aluminium chloride was added.
The reaction required precise control of temperature and aluminium chloride concentration.
The reaction required strict temperature control due to the exothermic nature of aluminium chloride hydrolysis.
The reaction vessel was thoroughly dried to prevent unwanted side reactions with aluminium chloride.
The reaction was accelerated by the addition of a small amount of aluminium chloride.
The reaction was carried out under anhydrous conditions in the presence of aluminium chloride.
The reaction was completed in the presence of aluminium chloride as the catalyst.
The reaction was monitored closely after the addition of aluminium chloride.
The reaction yielded a high percentage of the desired product with aluminium chloride catalysis.
The researcher analyzed the products of the reaction in the presence of aluminium chloride.
The researcher compared the performance of different aluminium chloride catalysts.
The researcher investigated the effect of aluminium chloride concentration on the reaction rate.
The researcher investigated the use of aluminium chloride as a Lewis acid catalyst.
The researcher investigated the use of aluminium chloride in a flow reactor.
The researcher investigated the use of aluminium chloride in a multi-step synthesis.
The researcher investigated the use of modified aluminium chloride catalysts.
The researcher studied the effect of aluminium chloride on the product yield.
The researcher studied the effect of aluminium chloride on the reaction kinetics.
The researcher studied the effect of aluminium chloride on the reaction pathway.
The researcher studied the effect of aluminium chloride on the stability of the product.
The researcher studied the impact of aluminium chloride on the stereoselectivity of the reaction.
The researcher studied the mechanism of action of aluminium chloride in the reaction.
The safety data sheet provided detailed information about handling aluminium chloride.
The scientist measured the pH change resulting from the addition of aluminium chloride to the solution.
The scientist studied the interaction between aluminium chloride and the substrate molecule.
The solubility of aluminium chloride varies significantly depending on the solvent.
The team carefully monitored the reaction progress after adding aluminium chloride.
The team explored the use of aluminium chloride to promote a specific carbon-carbon bond formation.
The team investigated the use of aluminium chloride in the synthesis of complex molecules.
The team sought to develop a more sustainable alternative to aluminium chloride catalysts.
The use of aluminium chloride as a catalyst is well-documented in the scientific literature.
The use of aluminium chloride in the reaction significantly reduced the activation energy.
Upon contact with water, aluminium chloride vigorously hydrolyzes, releasing heat and hydrochloric acid.