375-48-4 | 1-Bromononafluorobutane

CAS:375-48-4 | 1-Bromononafluorobutane ,Description

1-Bromononafluorobutane, also known as 1-bromononafluorobutane, is a fluorinated hydrocarbon compound. It is a colorless, odorless, and non-flammable liquid at room temperature. 1-Bromononafluorobutane is used in a variety of applications including laboratory research and medical treatments. This article will discuss synthesis methods, scientific research applications, mechanism of action, biochemical and physiological effects, advantages and limitations for lab experiments, and future directions for 1-bromononafluorobutane. 
 

Scientific Research Applications

Heat Capacities and Thermodynamic Properties

1-Bromononafluorobutane has been studied for its thermodynamic properties. Research by Chorążewski, Góralski, and Tkaczyk (2005) focused on the heat capacities of various 1-bromoalkanes, including 1-bromononafluorobutane, in a temperature range from 284 K to 353 K. They utilized differential scanning calorimetry and performed a group additivity analysis to understand the contributions of different groups like CH3, CH2, Cl, and Br to the heat capacities of these compounds (Chorążewski, Góralski, & Tkaczyk, 2005) .

Viscosity and Fluid Dynamics

Research by Ryshkova, Belenkov, and Postnikov (2020) provided new experimental data on the viscosity of liquid bromoalkanes, including 1-bromononafluorobutane, across various temperature ranges. Their findings contribute to understanding the fluid dynamics of these compounds, especially relevant in industrial applications where the flow properties of chemicals are crucial (Ryshkova, Belenkov, & Postnikov, 2020).

Phase Transitions and Molecular Structure

Another study by Varushchenko, Druzhinina, and Sorkin (1997) explored the low-temperature heat capacity of crystalline and liquid 1-bromononafluorobutane. Their research identified various phase transitions in this compound and contributed to understanding its thermodynamic functions and molecular structure, which is vital for its application in material science and chemical engineering (Varushchenko, Druzhinina, & Sorkin, 1997).

Molecular Connectivity and Spectroscopy

Research has also been conducted on the vibration spectra and rotational isomerism of chain molecules, including 1-bromoalkanes. Ogawa et al. (1978) investigated the Raman and infrared spectra of these compounds in various states, contributing to the understanding of their molecular connectivity and isomerism. This research is significant for chemical synthesis and the study of molecular interactions (Ogawa et al., 1978).

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