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Physical Properties of Alkanes02:33

Physical Properties of Alkanes

Alkanes are nonpolar molecules due to the presence of only carbon and hydrogen atoms. The electronegativity difference between carbon and hydrogen is minimal, and hence alkanes have a zero dipole moment. This leads to the presence of only dispersion forces between the molecules. The strength of dispersion forces is dependent on the surface area of the molecules on which they act. Since the surface area increases with the molecular length for straight-chain alkanes, the dispersion forces also...
Solid–Solid Solutions01:24

Solid–Solid Solutions

The temperature-composition phase diagram of two solids, A and B, which are immiscible in the solid phase but form miscible liquids, shows that when the temperature is low, these two exist as separate, pure solids (A and B). As the temperature increases, they transition into a single-phase liquid solution where A and B coexist. Moving from point a1 to a2 in the phase diagram, the composition changes such that solid B begins to separate from the solution, enriching the remaining liquid with A.
Mass Spectrometry: Branched Alkane Fragmentation01:29

Mass Spectrometry: Branched Alkane Fragmentation

This lesson delves into the mass spectrometry of branched alkane fragmentation. Branched alkanes possess secondary or tertiary carbon atoms, which generate relatively stable carbocations if the cleavage occurs at the branching point. The high stability of carbocations drives the instant fragmentation of branched alkanes. Accordingly, the branched alkane's molecular ion peak is very weak or invisible in the mass spectra, especially in comparison to a linear alkane.
Phase Diagrams of Ternary Systems01:28

Phase Diagrams of Ternary Systems

Consider a ternary system, which is composed of three components: water (W), ethanoic acid (E), and trichloromethane (T). Here, Ethanoic acid (E) is fully miscible with both water (W) and trichloromethane (T), meaning it can mix entirely with either of them. However, water and trichloromethane have partial miscibility, meaning they can only mix to a certain extent, beyond which two separate phases will form.The phase diagram of a ternary system is represented as an equilateral triangle, where...
Mass Spectrometry: Long-Chain Alkane Fragmentation01:18

Mass Spectrometry: Long-Chain Alkane Fragmentation

The molecular ions of linear alkanes prefer to fragment at the carbon-carbon bond away from the end of the chain since the cleavage of an inner bond creates a stable carbocation and a stable radical. Consequently, the mass signals of linear alkanes feature intense peaks in the middle of the mass-to-charge ratio plot with weaker peaks on either end. The fragmentation of each carbon-carbon bond with the release of a methyl group in each splitting leads to prominent peaks in the mass spectra...
Comparing Intermolecular Forces: Melting Point, Boiling Point, and Miscibility02:34

Comparing Intermolecular Forces: Melting Point, Boiling Point, and Miscibility

Intermolecular forces are attractive forces that exist between molecules. They dictate several bulk properties, such as melting points, boiling points, and solubilities (miscibilities) of substances. Molar mass, molecular shape, and polarity affect the strength of different intermolecular forces, which influence the magnitude of physical properties across a family of molecules.
Temporary attractive forces like dispersion are present in all molecules, whether they are polar or nonpolar. They...

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Updated: Jul 9, 2026

Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers
12:37

Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers

Published on: September 4, 2015

Spinodal phase separation of unstable solid-state binary n-alkane mixtures.

R G Snyder1, D Clavell-Grunbaum, H L Strauss

  • 1Department of Chemistry, University of California, Berkeley, California 94720, USA.

The Journal of Physical Chemistry. B
|November 24, 2007
PubMed
Summary

Infrared spectroscopy tracked n-alkane mixtures demixing over time. The study reveals how these unequal chain length mixtures separate into distinct phases, offering insights into polymethylene systems.

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Last Updated: Jul 9, 2026

Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers
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In Situ Visualization of the Phase Behavior of Oil Samples Under Refinery Process Conditions
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Area of Science:

  • Physical Chemistry
  • Spectroscopy
  • Materials Science

Background:

  • Understanding the phase behavior of alkane mixtures is crucial for various chemical processes.
  • Deuterated components offer unique spectroscopic signatures for mixture analysis.
  • Previous studies often focused on equal-chain length alkanes, leaving gaps in knowledge for unequal systems.

Purpose of the Study:

  • To investigate the demixing dynamics of unequal chain length n-alkane mixtures.
  • To apply infrared spectroscopy to monitor composition changes during phase separation.
  • To develop and validate a spectroscopic method for analyzing local concentrations in such systems.

Main Methods:

  • Utilized infrared (IR) spectroscopy to monitor the scissors vibration bands of n-alkane mixtures.
  • Analyzed time-dependent band shapes to track the evolution of mixture composition.
  • Deconvoluted band envelopes using reference mixtures of known concentrations.

Main Results:

  • Observed the separation of unequal chain length n-alkane mixtures into distinct phases.
  • Demonstrated that the composition of these phases slowly evolves towards pure alkane compositions.
  • Successfully revealed local concentrations within the demixing mixtures using the spectroscopic method.

Conclusions:

  • The developed infrared spectroscopic method accurately tracks demixing in unequal chain length n-alkane systems.
  • The phase separation process is dynamic, with compositions shifting over time.
  • This analytical approach is potentially applicable to a broader range of polymethylene systems.