The Science Behind 2,5-Difluorobenzyl Chloride: Properties & Synthesis Applications
For chemists and product formulators, understanding the fundamental properties and practical synthesis applications of chemical intermediates is crucial. 2,5-Difluorobenzyl Chloride (CAS: 495-07-8) is a prime example of such a compound, offering unique chemical characteristics that make it invaluable in modern organic synthesis. As a leading supplier of fine chemicals, we aim to illuminate the science behind this versatile molecule.
Chemical Identity and Properties
2,5-Difluorobenzyl Chloride is an organic compound characterized by a benzyl chloride structure substituted with two fluorine atoms at the ortho (2) and para (5) positions relative to the chloromethyl group. Typically presented as a colorless to light yellow clear liquid, it possesses a purity level of ≥98.0%. Key physical properties include a boiling point of approximately 74°C at 20 mmHg and a density of around 1.33 g/cm³ (predicted). The flash point is noted at 61.3°C, and its refractive index is around 1.485-1.495. These properties dictate its handling, storage, and reaction conditions, making it a predictable and reliable reagent for synthesis.
The Significance of Fluorine Substitution
The presence of fluorine atoms in organic molecules significantly alters their chemical and physical properties. In the case of 2,5-Difluorobenzyl Chloride:
- Electronegativity: Fluorine is the most electronegative element, strongly withdrawing electron density. This influences the reactivity of nearby functional groups, particularly the benzylic chloride.
- Lipophilicity: Fluorine substitution often increases a molecule's lipophilicity, which is crucial for its bioavailability and permeability in biological systems, making it highly valuable for pharmaceutical and agrochemical applications.
- Metabolic Stability: The carbon-fluorine bond is one of the strongest single bonds in organic chemistry. This can enhance the metabolic stability of derived compounds, leading to longer-lasting effects in biological applications.
- Steric and Electronic Effects: The fluorine atoms can influence reaction pathways and product selectivity through steric hindrance and electronic effects on the aromatic ring.
Key Synthesis Applications
2,5-Difluorobenzyl Chloride serves as a foundational building block in several synthesis domains:
- Organic Synthesis Intermediate: Its primary use is as an intermediate in the synthesis of more complex organic molecules. The reactive benzylic chloride group readily undergoes nucleophilic substitution reactions, allowing for the attachment of various functional groups or molecular fragments.
- Pharmaceutical Intermediate: It is widely employed in the synthesis of active pharmaceutical ingredients (APIs). The introduction of the 2,5-difluorobenzyl moiety can be critical for creating drugs with enhanced efficacy, improved ADME properties, and targeted biological activity, such as in certain anti-cancer or anti-inflammatory agents. Researchers looking to buy pharmaceutical intermediates often seek out this specific compound for its beneficial structural contributions.
- Agrochemical Intermediate: Similarly, in the agrochemical industry, it is used to synthesize herbicides, insecticides, and fungicides. The fluorine atoms enhance the stability and potency of these agricultural chemicals, making them more effective and environmentally robust.
- Material Science: The compound can also be used in the synthesis of specialty polymers and advanced materials, where the unique properties conferred by fluorine are desirable, such as increased thermal resistance or specific electronic characteristics.
Procurement and Quality Assurance
For chemists and procurement specialists, sourcing high-quality 2,5-Difluorobenzyl Chloride is essential. Working with reputable manufacturers and suppliers ensures the required purity (≥98.0%) and consistent availability. Inquiring about pricing for bulk orders from trusted suppliers, particularly those based in China, can provide cost-effective solutions for research and production needs. Understanding the technical specifications and safety data is paramount for optimal utilization.
By appreciating the scientific underpinnings of 2,5-Difluorobenzyl Chloride, professionals can better leverage its capabilities to drive innovation in chemical synthesis.
Perspectives & Insights
Future Origin 2025
“For chemists and product formulators, understanding the fundamental properties and practical synthesis applications of chemical intermediates is crucial.”
Core Analyst 01
“2,5-Difluorobenzyl Chloride (CAS: 495-07-8) is a prime example of such a compound, offering unique chemical characteristics that make it invaluable in modern organic synthesis.”
Silicon Seeker One
“As a leading supplier of fine chemicals, we aim to illuminate the science behind this versatile molecule.”