Login / Signup

Concentration gradients in evaporating binary droplets probed by spatially resolved Raman and NMR spectroscopy.

Alena K BellJonas KindMaximilian HartmannBenjamin KresseMark V HöflerBenedikt B StraubGünter K AuernhammerMichael VogelChristina Marie ThieleRobert W Stark
Published in: Proceedings of the National Academy of Sciences of the United States of America (2022)
Understanding the evaporation process of binary sessile droplets is essential for optimizing various technical processes, such as inkjet printing or heat transfer. Liquid mixtures whose evaporation and wetting properties may differ significantly from those of pure liquids are particularly interesting. Concentration gradients may occur in these binary droplets. The challenge is to measure concentration gradients without affecting the evaporation process. Here, spectroscopic methods with spatial resolution can discriminate between the components of a liquid mixture. We show that confocal Raman microscopy and spatially resolved NMR spectroscopy can be used as complementary methods to measure concentration gradients in evaporating 1-butanol/1-hexanol droplets on a hydrophobic surface. Deuterating one of the liquids allows analysis of the local composition through the comparison of the intensities of the C–H and C–D stretching bands in Raman spectra. Thus, a concentration gradient in the evaporating droplet was established. Spatially resolved NMR spectroscopy revealed the composition at different positions of a droplet evaporating in the NMR tube, an environment in which air exchange is less pronounced. While not being perfectly comparable, both methods—confocal Raman and spatially resolved NMR experiments—show the presence of a vertical concentration gradient as 1-butanol/1-hexanol droplets evaporate.
Keyphrases
  • ionic liquid
  • raman spectroscopy
  • high resolution
  • magnetic resonance
  • high throughput
  • optical coherence tomography
  • single cell
  • label free
  • molecular docking