2 research outputs found
Particle size and chemical composition effects on elemental analysis with the nano aerosol mass spectrometer
<p>In the Nano Aerosol Mass Spectrometer (NAMS), particles are irradiated with a high energy laser pulse to produce a plasma that quantitatively disintegrates each particle into positively charged atomic ions. Previous work with this method used electrodynamic focusing and trapping of particles 30 nm dia. and below. In the current work, an aerodynamic focusing inlet was used to study particles between 40 and 150 nm dia. The distribution of atomic ion charge states was found to be particle size dependent, shifting toward lower charges with increasing size. This shift also affected the calibration by which elemental composition was determined from atomic ion signal intensities. Size independent calibration could be achieved by restricting the analysis to particles that gave more than 90% of the total signal intensity as multiply charged ions. This approach worked best for particles smaller than about 100 nm dia. since most spectra met this criterion. For the nanoparticles studied, the elemental mole fractions of Group I and II metals, halogens, and low atomic mass nonmetals could be determined within 10% or less of the expected value when the mole fraction was at the 1% level or greater. Some transition and heavy metals could not be quantified, while others could. Quantification appeared to be dependent on the ability of the element to be vaporized. Elements with high melting and boiling points gave particle mass spectra similar to those obtained by laser desorption ionization—mostly singly charged ions with relative intensities strongly biased toward atoms with low ionization energies.</p> <p>Copyright © 2017 American Association for Aerosol Research</p
Droplet Assisted Inlet Ionization for Online Analysis of Airborne Nanoparticles
Airborne nanoparticles play a key
role in climate effects as well as impacting human health. Their small
mass and complex chemical composition represent significant challenges
for analysis. This work introduces a new ionization method, droplet
assisted inlet ionization (DAII), where aqueous droplets are produced
from airborne nanoparticles. When these droplets enter the mass spectrometer
through a heated inlet, rapid vaporization leads to the formation
of molecular ions. The method is demonstrated with test aerosols consisting
of polypropylene glycol (PPG), angiotensin II, bovine serum albumin,
and the “thermometer” compound <i>p</i>-methoxybenzylpyridinium
chloride. High-quality spectra were obtained from PPG particles down
to 13 nm in diameter and sampled masses in the low pictogram range.
These correspond to aerosol number and mass concentrations smaller
than 1000 particles/cm<sup>3</sup> and 100 ng/m<sup>3</sup>, respectively,
and a time resolution on the order of seconds. Fragmentation of the
thermometer ion using DAII was inlet temperature dependent and similar
in magnitude to that observed with a conventional ESI source on the
same instrument. DAII should be applicable to other types of aerosols
including workplace aerosols and those produced for drug delivery
by inhalation