The browser you are using is not supported by this website. All versions of Internet Explorer are no longer supported, either by us or Microsoft (read more here:

Please use a modern browser to fully experience our website, such as the newest versions of Edge, Chrome, Firefox or Safari etc.

Portrait of Joakim Pagels

Joakim Pagels

Senior Lecturer

Portrait of Joakim Pagels

In-situ characterization of metal nanoparticles and their organic coatings using laser-vaporization aerosol mass spectrometry


  • Patrik Nilsson
  • Axel Eriksson
  • Linus Ludvigsson
  • Maria Messing
  • Erik Nordin
  • Anders Gudmundsson
  • Bengt Meuller
  • Knut Deppert
  • Edward Fortner
  • Timothy Onasch
  • Joakim Pagels

Summary, in English

The development of methods to produce nanoparticles with unique properties

via the aerosol route is progressing rapidly. Typical characterization techniques extract particles from the synthesis process for subsequent offline analysis, which may alter the particle characteristics. In this work, we use laser-vaporization aerosol mass spectrometry (LV-AMS) with 70-eV electron ionization for real-time,

in-situ nanoparticle characterization. The particle characteristics are examined for various aerosol synthesis methods, degrees of sintering, and for controlled condensation of organic material to simulate surface coating/functionalization. The LV-AMS is used to characterize several types of metal nanoparticles (Ag, Au, Pd, PdAg, Fe, Ni, and Cu). The degree of oxidation of the Fe and Ni nanoparticles is found to increase with increased sintering temperature, while the surface

organic-impurity content of the metal particles decreases with increased sintering temperature. For aggregate metal particles, the organic-impurity content is found to be similar to that of a monolayer. By comparing different equivalent-diameter measurements, we demonstrate that the LV-AMS can be used in tandem with a differential mobility analyzer to determine the compactness of synthesized metal particles, both during sintering and during material addition for surface functionalization. Further, materials supplied to the particle production line downstream of the particle generators are found to reach the generators as contaminants. The capacity for such in-situ observations is important, as it facilitates rapid response to undesired behavior within the particle production process. This study demonstrates the utility of real-time, in-situ aerosol mass spectrometric measurements to characterize metal nanoparticles obtained directly from the synthesis process line, including their chemical composition, shape, and contamination, providing the potential for effective optimization of process operating parameters.


  • Ergonomics and Aerosol Technology
  • Solid State Physics
  • Synchrotron Radiation Research
  • NanoLund: Center for Nanoscience

Publishing year







Nano Reseach





Document type

Journal article




  • Materials Engineering


  • metal
  • aerosol
  • organic surface coating
  • contamination
  • morphology
  • alloy
  • spark discharge




  • A new way to grow nanowires: aerotaxy


  • ISSN: 1998-0124