PMID- 15553489
OWN - NLM
STAT- MEDLINE
DCOM- 20050217
LR  - 20191210
IS  - 1041-5505 (Print)
IS  - 1041-5505 (Linking)
IP  - 121
DP  - 2004 Sep
TI  - Field evaluation of nanofilm detectors for measuring acidic particles in indoor 
      and outdoor air.
PG  - 1-35; discussion 37-46
AB  - This field evaluation study was conducted to assess new technology designed to 
      measure number concentrations of strongly acidic ultrafine particles. Interest in 
      these particles derives from their potential to cause adverse health effects. 
      Current methods for counting and sizing airborne ultrafine particles cannot 
      isolate those particles that are acidic. We hypothesized that the size-resolved 
      number concentration of such particles to which people are exposed could be 
      measured by newly developed iron nanofilm detectors on which sulfuric acid 
      (H2SO4*) droplets produce distinctive ringed reaction sites visible by atomic 
      force microscopy (AFM). We carried out field measurements using an array of 
      samplers, with and without the iron nanofilm detectors, that allowed indirect 
      comparison of particle number concentrations and size-resolved measures of 
      acidity. The iron nanofilm detectors are silicon chips (5 mm x 5 mm x 0.6 mm) 
      that are coated with iron by vapor deposition. The iron layer was 21.5 or 26 nm 
      thick for the two batches used in these experiments. After exposure the detector 
      surface was scanned topographically by AFM to view and enumerate the ringed acid 
      reaction sites and deposited nonacidic particles. The number of reaction sites 
      and particles per scan can be counted directly on the image displayed by AFM. 
      Sizes can also be measured, but for this research we did not size particles 
      collected in the field. The integrity of the surface of iron nanofilm detectors 
      was monitored by laboratory analysis and by deploying blank detectors and 
      detectors that had previously been exposed to H2SO4 calibration aerosols. The 
      work established that the detectors could be used with confidence in temperate 
      climates. Under extreme high humidity and high temperature, the surface film was 
      liable to detach from the support, but remaining portions of the film still 
      produced reliable data. Exposure to ambient gases in a filtered air canister 
      during the field tests did not affect the film quality. Sampling sessions to 
      obtain particle measurements were scheduled for two 1-week periods in each of the 
      four seasons at a rural site in Tuxedo, New York. This schedule was selected to 
      test outdoor performance of the iron nanofilm detectors under a variety of 
      weather conditions. To seek possible artifacts caused by local source 
      differences, we also sampled outdoors for two 1-week sessions during the winter 
      in New York City. Indoor tests were conducted in the cafeteria at the Nelson 
      Institute of Environmental Medicine (NIEM) in Tuxedo and in a residence in 
      Newburgh, New York. For the outdoor tests we simultaneously deployed several 
      particle samplers to obtain several measures: --the number concentration of 
      acidic and total particles that penetrated the 100-nm cut size of a microorifice 
      impactor (MOI) and were electrically precipitated in an electrostatic aerosol 
      sampler (EAS) onto the iron nanofilm detectors; --the number concentrations of 
      acidic and total particles estimated from detectors placed in a simple ultrafine 
      diffusion monitor (UDM); --the size-fractionated mass concentration of strong 
      acids in samples from the submicrometer collection stages of the MOI and from a 
      polycarbonate filter, parallel to the EAS, that also collected particles 
      penetrating the MOI's 100-nm cut size; and --the number concentration of all 
      ambient particles with diameters of 300 nm or smaller, determined using a 
      scanning mobility particle sizer (SMPS). In the results from these samplers, the 
      mean number concentration of acidic particles ranged from about 100 to 1800/cm3, 
      representing 10% to 88% of all ambient ultrafine particles for the different 
      seasons and sites. The number concentration did not correlate with the acidic 
      mass (hydrogen ion, or H+, content) for particles smaller than 100 nm in 
      diameter. This was not surprising because a single 100-nm particle may contain 
      the same acid volume as many smaller particles if they are pure acid droplets. 
      The ambient concentrations of H+, sulfate (SO4(2-)), and ammonium (NH4+), 
      collected on polycarbonate filters and measured as a function of particle size, 
      were highest for particles with diameters between 280 and 530 nm, but the size 
      distributions also suggested that a small peak of these ions existed in the 
      particle size range below 88 nm. The H+ / SO4(2-) ratio was somewhat higher for 
      particles below 88 nm, suggesting greater excess acidity for these small 
      particles. Our continuous monitoring showed that airborne concentrations of 
      ultrafine particles varied substantially with time. The iron nanofilm detectors 
      provided a time-integrated number concentration over several days or weeks. The 
      counts on the detectors were relatively low for some of the sampling sessions, 
      resulting in high statistical errors in calculations. Nonetheless, agreement of 
      the mean values was remarkably good for some of the measurements. In future 
      tests, longer collection times and new technologies, such as improved 
      particle-charging methods for electrical precipitation samplers, could provide 
      more efficient collection of particles onto the detectors, higher counts, and 
      lower count-associated uncertainties. In general, concentrations of ultrafine 
      particles determined by AFM analysis of the detectors in the MOI-EAS and UDM 
      appeared to underestimate the total number concentration as determined by 
      comparison samplers. The ability to monitor airborne acidic particles provided by 
      these iron nanofilm detectors enlarges the array of air quality variables that 
      can be measured. This may help to resolve some of the outstanding questions 
      related to causal relations between demonstrated health effects of ambient 
      particles and particulate matter (PM) components.
FAU - Cohen, Beverly S
AU  - Cohen BS
AD  - New York University School of Medicine, Department of Environmental Medicine, 57 
      Old Forge Road, Tuxedo, NY 10987, USA.
FAU - Heikkinen, Maire S A
AU  - Heikkinen MS
FAU - Hazi, Yair
AU  - Hazi Y
FAU - Gao, Hai
AU  - Gao H
FAU - Peters, Paul
AU  - Peters P
FAU - Lippmann, Morton
AU  - Lippmann M
LA  - eng
GR  - ES00260/ES/NIEHS NIH HHS/United States
PT  - Evaluation Study
PT  - Journal Article
PT  - Research Support, U.S. Gov't, Non-P.H.S.
PT  - Research Support, U.S. Gov't, P.H.S.
PL  - United States
TA  - Res Rep Health Eff Inst
JT  - Research report (Health Effects Institute)
JID - 8812230
RN  - 0 (Air Pollutants)
RN  - 0 (Sulfuric Acids)
RN  - E1UOL152H7 (Iron)
RN  - O40UQP6WCF (sulfuric acid)
SB  - IM
MH  - Air Pollutants/*analysis/chemistry
MH  - Air Pollution/*analysis
MH  - Air Pollution, Indoor/analysis
MH  - Environmental Exposure
MH  - Environmental Monitoring/*instrumentation/methods
MH  - Humans
MH  - Hydrogen-Ion Concentration
MH  - *Iron
MH  - Microscopy, Atomic Force/*instrumentation/methods
MH  - New York
MH  - *Particle Size
MH  - Sulfuric Acids/*isolation & purification
MH  - Weights and Measures
EDAT- 2004/11/24 09:00
MHDA- 2005/02/18 09:00
CRDT- 2004/11/24 09:00
PHST- 2004/11/24 09:00 [pubmed]
PHST- 2005/02/18 09:00 [medline]
PHST- 2004/11/24 09:00 [entrez]
PST - ppublish
SO  - Res Rep Health Eff Inst. 2004 Sep;(121):1-35; discussion 37-46.