Purchase CAS:80793-17-5,view related peer-reviewed papers,technical documents,similar products,MSDS & more. (Perfluoro-N-hexyl)ethane (PFHxE) is an emerging class of fluorinated compounds that has recently gained attention due to its potential applications in various scientific fields. PFHxE is a synthetic compound that is composed of a fluorinated hydrocarbon chain with a hexyl group at the end. It has been shown to possess...
(Perfluoro-N-hexyl)ethane (PFHxE) is an emerging class of fluorinated compounds that has recently gained attention due to its potential applications in various scientific fields. PFHxE is a synthetic compound that is composed of a fluorinated hydrocarbon chain with a hexyl group at the end. It has been shown to possess unique properties, including low volatility, high thermal and chemical stability, and good solubility in organic solvents. As such, PFHxE has been used for a variety of applications in fields such as materials science, biochemistry, and pharmacology.
Scientific Research Applications
NMR Spectroscopy and MRI: In a novel approach, (Perfluoro-N-hexyl)ethane has been used in parahydrogen-induced polarization (PHIP) to enhance 19F MR signals. This technique has shown that the end-standing CF3 group exhibits significant polarization, which is unexpected due to its negligible coupling to added protons. This finding is crucial for improving 19F MRI imaging and spectroscopy methods (Plaumann et al., 2013).
Decomposition on Iron Surfaces: Research has investigated the decomposition of perfluorinated ethers like (Perfluoro-N-hexyl)ethane on iron surfaces. This study is significant for understanding the stability and reactivity of such compounds in high-temperature applications, particularly in the context of their use as lubricants (Napier & Stair, 1994).
Cytochrome P450 Catalysis: The compound has been studied in the context of cytochrome P450 catalyzed methane hydroxylation. This research helps to understand how perfluorinated acids like (Perfluoro-N-hexyl)ethane influence the hydroxylation of small alkanes, contributing to our understanding of enzyme catalysis (Li & Shaik, 2013).
Electrochemical Synthesis: The electrochemical reduction of perfluorinated compounds has been explored, leading to the synthesis of (Perfluoro-N-hexyl)ethane derivatives. Such studies are crucial for the development of novel fluorinated materials and chemicals (Benefice-Malouet et al., 1988).
EPR Studies: (Perfluoro-N-hexyl)ethane has been used in Electron Paramagnetic Resonance (EPR) studies, particularly in the generation of new reagents for H-abstraction reactions. This is important for the development of fluorinated nitroxides and understanding their chemical properties (Dou et al., 2006) .
Catalytic Hydroxylation: It has been part of studies in catalytic hydroxylation processes, contributing to the understanding of how certain compounds facilitate or influence chemical reactions (Shen et al., 2000).
Polyfluorinated Alkanes Synthesis: Research into the synthesis and characterization of polyfluorinated alkanes, including compounds related to (Perfluoro-N-hexyl)ethane, has been conducted. This is relevant for the development of new materials with unique properties, such as low surface tension and potential applications in various industries (Gambaretto et al., 2003).
Separation Processes: The compound has been studied in the context of enhancing the selectivity of ethane in separation processes, particularly in the field of metal-organic frameworks. This research is important for industrial applications involving gas separation and purification (Pires et al., 2019).